drivers/net/fsl-mc/dpio/qbman_portal.h - manifest_repos/bootloader - Git at Google

 /*
  * Copyright (C) 2014 Freescale Semiconductor
  *
  * SPDX-License-Identifier:	GPL-2.0+
  */

 #include "qbman_private.h"
 #include <fsl-mc/fsl_qbman_portal.h>
 #include <fsl-mc/fsl_dpaa_fd.h>

 /* All QBMan command and result structures use this "valid bit" encoding */
 #define QB_VALID_BIT ((uint32_t)0x80)

 /* Management command result codes */
 #define QBMAN_MC_RSLT_OK      0xf0

 /* TBD: as of QBMan 4.1, DQRR will be 8 rather than 4! */
 #define QBMAN_DQRR_SIZE 4


 /* --------------------- */
 /* portal data structure */
 /* --------------------- */

 struct qbman_swp {
 	const struct qbman_swp_desc *desc;
 	/* The qbman_sys (ie. arch/OS-specific) support code can put anything it
 	 * needs in here. */
 	struct qbman_swp_sys sys;
 	/* Management commands */
 	struct {
 #ifdef QBMAN_CHECKING
 		enum swp_mc_check {
 			swp_mc_can_start, /* call __qbman_swp_mc_start() */
 			swp_mc_can_submit, /* call __qbman_swp_mc_submit() */
 			swp_mc_can_poll, /* call __qbman_swp_mc_result() */
 		} check;
 #endif
 		uint32_t valid_bit; /* 0x00 or 0x80 */
 	} mc;
 	/* Push dequeues */
 	uint32_t sdq;
 	/* Volatile dequeues */
 	struct {
 		/* VDQCR supports a "1 deep pipeline", meaning that if you know
 		 * the last-submitted command is already executing in the
 		 * hardware (as evidenced by at least 1 valid dequeue result),
 		 * you can write another dequeue command to the register, the
 		 * hardware will start executing it as soon as the
 		 * already-executing command terminates. (This minimises latency
 		 * and stalls.) With that in mind, this "busy" variable refers
 		 * to whether or not a command can be submitted, not whether or
 		 * not a previously-submitted command is still executing. In
 		 * other words, once proof is seen that the previously-submitted
 		 * command is executing, "vdq" is no longer "busy".
 		 */
 		atomic_t busy;
 		uint32_t valid_bit; /* 0x00 or 0x80 */
 		/* We need to determine when vdq is no longer busy. This depends
 		 * on whether the "busy" (last-submitted) dequeue command is
 		 * targeting DQRR or main-memory, and detected is based on the
 		 * presence of the dequeue command's "token" showing up in
 		 * dequeue entries in DQRR or main-memory (respectively). Debug
 		 * builds will, when submitting vdq commands, verify that the
 		 * dequeue result location is not already equal to the command's
 		 * token value. */
 		struct ldpaa_dq *storage; /* NULL if DQRR */
 		uint32_t token;
 	} vdq;
 	/* DQRR */
 	struct {
 		uint32_t next_idx;
 		uint32_t valid_bit;
 	} dqrr;
 };

 /* -------------------------- */
 /* portal management commands */
 /* -------------------------- */

 /* Different management commands all use this common base layer of code to issue
  * commands and poll for results. The first function returns a pointer to where
  * the caller should fill in their MC command (though they should ignore the
  * verb byte), the second function commits merges in the caller-supplied command
  * verb (which should not include the valid-bit) and submits the command to
  * hardware, and the third function checks for a completed response (returns
  * non-NULL if only if the response is complete). */
 void *qbman_swp_mc_start(struct qbman_swp *p);
 void qbman_swp_mc_submit(struct qbman_swp *p, void *cmd, uint32_t cmd_verb);
 void *qbman_swp_mc_result(struct qbman_swp *p);

 /* Wraps up submit + poll-for-result */
 static inline void *qbman_swp_mc_complete(struct qbman_swp *swp, void *cmd,
 					  uint32_t cmd_verb)
 {
 	int loopvar;

 	qbman_swp_mc_submit(swp, cmd, cmd_verb);
 	DBG_POLL_START(loopvar);
 	do {
 		DBG_POLL_CHECK(loopvar);
 		cmd = qbman_swp_mc_result(swp);
 	} while (!cmd);
 	return cmd;
 }

 /* ------------ */
 /* qb_attr_code */
 /* ------------ */

 /* This struct locates a sub-field within a QBMan portal (CENA) cacheline which
  * is either serving as a configuration command or a query result. The
  * representation is inherently little-endian, as the indexing of the words is
  * itself little-endian in nature and layerscape is little endian for anything
  * that crosses a word boundary too (64-bit fields are the obvious examples).
  */
 struct qb_attr_code {
 	unsigned int word; /* which uint32_t[] array member encodes the field */
 	unsigned int lsoffset; /* encoding offset from ls-bit */
 	unsigned int width; /* encoding width. (bool must be 1.) */
 };

 /* Macros to define codes */
 #define QB_CODE(a, b, c) { a, b, c}

 /* decode a field from a cacheline */
 static inline uint32_t qb_attr_code_decode(const struct qb_attr_code *code,
 				      const uint32_t *cacheline)
 {
 	return d32_uint32_t(code->lsoffset, code->width, cacheline[code->word]);
 }


 /* encode a field to a cacheline */
 static inline void qb_attr_code_encode(const struct qb_attr_code *code,
 				       uint32_t *cacheline, uint32_t val)
 {
 	cacheline[code->word] =
 		r32_uint32_t(code->lsoffset, code->width, cacheline[code->word])
 		| e32_uint32_t(code->lsoffset, code->width, val);
 }

 static inline void qb_attr_code_encode_64(const struct qb_attr_code *code,
 				       uint64_t *cacheline, uint64_t val)
 {
 	cacheline[code->word / 2] = val;
 }

 /* ---------------------- */
 /* Descriptors/cachelines */
 /* ---------------------- */

 /* To avoid needless dynamic allocation, the driver API often gives the caller
  * a "descriptor" type that the caller can instantiate however they like.
  * Ultimately though, it is just a cacheline of binary storage (or something
  * smaller when it is known that the descriptor doesn't need all 64 bytes) for
  * holding pre-formatted pieces of hardware commands. The performance-critical
  * code can then copy these descriptors directly into hardware command
  * registers more efficiently than trying to construct/format commands
  * on-the-fly. The API user sees the descriptor as an array of 32-bit words in
  * order for the compiler to know its size, but the internal details are not
  * exposed. The following macro is used within the driver for converting *any*
  * descriptor pointer to a usable array pointer. The use of a macro (instead of
  * an inline) is necessary to work with different descriptor types and to work
  * correctly with const and non-const inputs (and similarly-qualified outputs).
  */
 #define qb_cl(d) (&(d)->dont_manipulate_directly[0])
	/*
	* Copyright (C) 2014 Freescale Semiconductor
	*
	* SPDX-License-Identifier: GPL-2.0+
	*/

	#include "qbman_private.h"
	#include <fsl-mc/fsl_qbman_portal.h>
	#include <fsl-mc/fsl_dpaa_fd.h>

	/* All QBMan command and result structures use this "valid bit" encoding */
	#define QB_VALID_BIT ((uint32_t)0x80)

	/* Management command result codes */
	#define QBMAN_MC_RSLT_OK 0xf0

	/* TBD: as of QBMan 4.1, DQRR will be 8 rather than 4! */
	#define QBMAN_DQRR_SIZE 4


	/* --------------------- */
	/* portal data structure */
	/* --------------------- */

	struct qbman_swp {
	const struct qbman_swp_desc *desc;
	/* The qbman_sys (ie. arch/OS-specific) support code can put anything it
	* needs in here. */
	struct qbman_swp_sys sys;
	/* Management commands */
	struct {
	#ifdef QBMAN_CHECKING
	enum swp_mc_check {
	swp_mc_can_start, /* call __qbman_swp_mc_start() */
	swp_mc_can_submit, /* call __qbman_swp_mc_submit() */
	swp_mc_can_poll, /* call __qbman_swp_mc_result() */
	} check;
	#endif
	uint32_t valid_bit; /* 0x00 or 0x80 */
	} mc;
	/* Push dequeues */
	uint32_t sdq;
	/* Volatile dequeues */
	struct {
	/* VDQCR supports a "1 deep pipeline", meaning that if you know
	* the last-submitted command is already executing in the
	* hardware (as evidenced by at least 1 valid dequeue result),
	* you can write another dequeue command to the register, the
	* hardware will start executing it as soon as the
	* already-executing command terminates. (This minimises latency
	* and stalls.) With that in mind, this "busy" variable refers
	* to whether or not a command can be submitted, not whether or
	* not a previously-submitted command is still executing. In
	* other words, once proof is seen that the previously-submitted
	* command is executing, "vdq" is no longer "busy".
	*/
	atomic_t busy;
	uint32_t valid_bit; /* 0x00 or 0x80 */
	/* We need to determine when vdq is no longer busy. This depends
	* on whether the "busy" (last-submitted) dequeue command is
	* targeting DQRR or main-memory, and detected is based on the
	* presence of the dequeue command's "token" showing up in
	* dequeue entries in DQRR or main-memory (respectively). Debug
	* builds will, when submitting vdq commands, verify that the
	* dequeue result location is not already equal to the command's
	* token value. */
	struct ldpaa_dq storage; / NULL if DQRR */
	uint32_t token;
	} vdq;
	/* DQRR */
	struct {
	uint32_t next_idx;
	uint32_t valid_bit;
	} dqrr;
	};

	/* -------------------------- */
	/* portal management commands */
	/* -------------------------- */

	/* Different management commands all use this common base layer of code to issue
	* commands and poll for results. The first function returns a pointer to where
	* the caller should fill in their MC command (though they should ignore the
	* verb byte), the second function commits merges in the caller-supplied command
	* verb (which should not include the valid-bit) and submits the command to
	* hardware, and the third function checks for a completed response (returns
	* non-NULL if only if the response is complete). */
	void qbman_swp_mc_start(struct qbman_swp p);
	void qbman_swp_mc_submit(struct qbman_swp p, void cmd, uint32_t cmd_verb);
	void qbman_swp_mc_result(struct qbman_swp p);

	/* Wraps up submit + poll-for-result */
	static inline void qbman_swp_mc_complete(struct qbman_swp swp, void *cmd,
	uint32_t cmd_verb)
	{
	int loopvar;

	qbman_swp_mc_submit(swp, cmd, cmd_verb);
	DBG_POLL_START(loopvar);
	do {
	DBG_POLL_CHECK(loopvar);
	cmd = qbman_swp_mc_result(swp);
	} while (!cmd);
	return cmd;
	}

	/* ------------ */
	/* qb_attr_code */
	/* ------------ */

	/* This struct locates a sub-field within a QBMan portal (CENA) cacheline which
	* is either serving as a configuration command or a query result. The
	* representation is inherently little-endian, as the indexing of the words is
	* itself little-endian in nature and layerscape is little endian for anything
	* that crosses a word boundary too (64-bit fields are the obvious examples).
	*/
	struct qb_attr_code {
	unsigned int word; /* which uint32_t[] array member encodes the field */
	unsigned int lsoffset; /* encoding offset from ls-bit */
	unsigned int width; /* encoding width. (bool must be 1.) */
	};

	/* Macros to define codes */
	#define QB_CODE(a, b, c) { a, b, c}

	/* decode a field from a cacheline */
	static inline uint32_t qb_attr_code_decode(const struct qb_attr_code *code,
	const uint32_t *cacheline)
	{
	return d32_uint32_t(code->lsoffset, code->width, cacheline[code->word]);
	}


	/* encode a field to a cacheline */
	static inline void qb_attr_code_encode(const struct qb_attr_code *code,
	uint32_t *cacheline, uint32_t val)
	{
	cacheline[code->word] =
	r32_uint32_t(code->lsoffset, code->width, cacheline[code->word])
	\| e32_uint32_t(code->lsoffset, code->width, val);
	}

	static inline void qb_attr_code_encode_64(const struct qb_attr_code *code,
	uint64_t *cacheline, uint64_t val)
	{
	cacheline[code->word / 2] = val;
	}

	/* ---------------------- */
	/* Descriptors/cachelines */
	/* ---------------------- */

	/* To avoid needless dynamic allocation, the driver API often gives the caller
	* a "descriptor" type that the caller can instantiate however they like.
	* Ultimately though, it is just a cacheline of binary storage (or something
	* smaller when it is known that the descriptor doesn't need all 64 bytes) for
	* holding pre-formatted pieces of hardware commands. The performance-critical
	* code can then copy these descriptors directly into hardware command
	* registers more efficiently than trying to construct/format commands
	* on-the-fly. The API user sees the descriptor as an array of 32-bit words in
	* order for the compiler to know its size, but the internal details are not
	* exposed. The following macro is used within the driver for converting any
	* descriptor pointer to a usable array pointer. The use of a macro (instead of
	* an inline) is necessary to work with different descriptor types and to work
	* correctly with const and non-const inputs (and similarly-qualified outputs).
	*/
	#define qb_cl(d) (&(d)->dont_manipulate_directly[0])