drivers/net/ethernet/netronome/nfp/nfpcore/nfp_nffw.c - hafnium/third_party/linux - Git at Google

 // SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
 /* Copyright (C) 2015-2018 Netronome Systems, Inc. */

 /*
  * nfp_nffw.c
  * Authors: Jakub Kicinski <jakub.kicinski@netronome.com>
  *          Jason McMullan <jason.mcmullan@netronome.com>
  *          Francois H. Theron <francois.theron@netronome.com>
  */

 #include <linux/kernel.h>
 #include <linux/slab.h>

 #include "nfp.h"
 #include "nfp_cpp.h"
 #include "nfp_nffw.h"
 #include "nfp6000/nfp6000.h"

 /* Init-CSR owner IDs for firmware map to firmware IDs which start at 4.
  * Lower IDs are reserved for target and loader IDs.
  */
 #define NFFW_FWID_EXT   3 /* For active MEs that we didn't load. */
 #define NFFW_FWID_BASE  4

 #define NFFW_FWID_ALL   255

 /**
  * NFFW_INFO_VERSION history:
  * 0: This was never actually used (before versioning), but it refers to
  *    the previous struct which had FWINFO_CNT = MEINFO_CNT = 120 that later
  *    changed to 200.
  * 1: First versioned struct, with
  *     FWINFO_CNT = 120
  *     MEINFO_CNT = 120
  * 2:  FWINFO_CNT = 200
  *     MEINFO_CNT = 200
  */
 #define NFFW_INFO_VERSION_CURRENT 2

 /* Enough for all current chip families */
 #define NFFW_MEINFO_CNT_V1 120
 #define NFFW_FWINFO_CNT_V1 120
 #define NFFW_MEINFO_CNT_V2 200
 #define NFFW_FWINFO_CNT_V2 200

 /* Work in 32-bit words to make cross-platform endianness easier to handle */

 /** nfp.nffw meinfo **/
 struct nffw_meinfo {
 	__le32 ctxmask__fwid__meid;
 };

 struct nffw_fwinfo {
 	__le32 loaded__mu_da__mip_off_hi;
 	__le32 mip_cppid; /* 0 means no MIP */
 	__le32 mip_offset_lo;
 };

 struct nfp_nffw_info_v1 {
 	struct nffw_meinfo meinfo[NFFW_MEINFO_CNT_V1];
 	struct nffw_fwinfo fwinfo[NFFW_FWINFO_CNT_V1];
 };

 struct nfp_nffw_info_v2 {
 	struct nffw_meinfo meinfo[NFFW_MEINFO_CNT_V2];
 	struct nffw_fwinfo fwinfo[NFFW_FWINFO_CNT_V2];
 };

 /** Resource: nfp.nffw main **/
 struct nfp_nffw_info_data {
 	__le32 flags[2];
 	union {
 		struct nfp_nffw_info_v1 v1;
 		struct nfp_nffw_info_v2 v2;
 	} info;
 };

 struct nfp_nffw_info {
 	struct nfp_cpp *cpp;
 	struct nfp_resource *res;

 	struct nfp_nffw_info_data fwinf;
 };

 /* flg_info_version = flags[0]<27:16>
  * This is a small version counter intended only to detect if the current
  * implementation can read the current struct. Struct changes should be very
  * rare and as such a 12-bit counter should cover large spans of time. By the
  * time it wraps around, we don't expect to have 4096 versions of this struct
  * to be in use at the same time.
  */
 static u32 nffw_res_info_version_get(const struct nfp_nffw_info_data *res)
 {
 	return (le32_to_cpu(res->flags[0]) >> 16) & 0xfff;
 }

 /* flg_init = flags[0]<0> */
 static u32 nffw_res_flg_init_get(const struct nfp_nffw_info_data *res)
 {
 	return (le32_to_cpu(res->flags[0]) >> 0) & 1;
 }

 /* loaded = loaded__mu_da__mip_off_hi<31:31> */
 static u32 nffw_fwinfo_loaded_get(const struct nffw_fwinfo *fi)
 {
 	return (le32_to_cpu(fi->loaded__mu_da__mip_off_hi) >> 31) & 1;
 }

 /* mip_cppid = mip_cppid */
 static u32 nffw_fwinfo_mip_cppid_get(const struct nffw_fwinfo *fi)
 {
 	return le32_to_cpu(fi->mip_cppid);
 }

 /* loaded = loaded__mu_da__mip_off_hi<8:8> */
 static u32 nffw_fwinfo_mip_mu_da_get(const struct nffw_fwinfo *fi)
 {
 	return (le32_to_cpu(fi->loaded__mu_da__mip_off_hi) >> 8) & 1;
 }

 /* mip_offset = (loaded__mu_da__mip_off_hi<7:0> << 8) | mip_offset_lo */
 static u64 nffw_fwinfo_mip_offset_get(const struct nffw_fwinfo *fi)
 {
 	u64 mip_off_hi = le32_to_cpu(fi->loaded__mu_da__mip_off_hi);

 	return (mip_off_hi & 0xFF) << 32 | le32_to_cpu(fi->mip_offset_lo);
 }

 static unsigned int
 nffw_res_fwinfos(struct nfp_nffw_info_data *fwinf, struct nffw_fwinfo **arr)
 {
 	/* For the this code, version 0 is most likely to be
 	 * version 1 in this case. Since the kernel driver
 	 * does not take responsibility for initialising the
 	 * nfp.nffw resource, any previous code (CA firmware or
 	 * userspace) that left the version 0 and did set
 	 * the init flag is going to be version 1.
 	 */
 	switch (nffw_res_info_version_get(fwinf)) {
 	case 0:
 	case 1:
 		*arr = &fwinf->info.v1.fwinfo[0];
 		return NFFW_FWINFO_CNT_V1;
 	case 2:
 		*arr = &fwinf->info.v2.fwinfo[0];
 		return NFFW_FWINFO_CNT_V2;
 	default:
 		*arr = NULL;
 		return 0;
 	}
 }

 /**
  * nfp_nffw_info_open() - Acquire the lock on the NFFW table
  * @cpp:	NFP CPP handle
  *
  * Return: pointer to nfp_nffw_info object or ERR_PTR()
  */
 struct nfp_nffw_info *nfp_nffw_info_open(struct nfp_cpp *cpp)
 {
 	struct nfp_nffw_info_data *fwinf;
 	struct nfp_nffw_info *state;
 	u32 info_ver;
 	int err;

 	state = kzalloc(sizeof(*state), GFP_KERNEL);
 	if (!state)
 		return ERR_PTR(-ENOMEM);

 	state->res = nfp_resource_acquire(cpp, NFP_RESOURCE_NFP_NFFW);
 	if (IS_ERR(state->res))
 		goto err_free;

 	fwinf = &state->fwinf;

 	if (sizeof(*fwinf) > nfp_resource_size(state->res))
 		goto err_release;

 	err = nfp_cpp_read(cpp, nfp_resource_cpp_id(state->res),
 			   nfp_resource_address(state->res),
 			   fwinf, sizeof(*fwinf));
 	if (err < (int)sizeof(*fwinf))
 		goto err_release;

 	if (!nffw_res_flg_init_get(fwinf))
 		goto err_release;

 	info_ver = nffw_res_info_version_get(fwinf);
 	if (info_ver > NFFW_INFO_VERSION_CURRENT)
 		goto err_release;

 	state->cpp = cpp;
 	return state;

 err_release:
 	nfp_resource_release(state->res);
 err_free:
 	kfree(state);
 	return ERR_PTR(-EIO);
 }

 /**
  * nfp_nffw_info_close() - Release the lock on the NFFW table and free state
  * @state:	NFP FW info state
  */
 void nfp_nffw_info_close(struct nfp_nffw_info *state)
 {
 	nfp_resource_release(state->res);
 	kfree(state);
 }

 /**
  * nfp_nffw_info_fwid_first() - Return the first firmware ID in the NFFW
  * @state:	NFP FW info state
  *
  * Return: First NFFW firmware info, NULL on failure
  */
 static struct nffw_fwinfo *nfp_nffw_info_fwid_first(struct nfp_nffw_info *state)
 {
 	struct nffw_fwinfo *fwinfo;
 	unsigned int cnt, i;

 	cnt = nffw_res_fwinfos(&state->fwinf, &fwinfo);
 	if (!cnt)
 		return NULL;

 	for (i = 0; i < cnt; i++)
 		if (nffw_fwinfo_loaded_get(&fwinfo[i]))
 			return &fwinfo[i];

 	return NULL;
 }

 /**
  * nfp_nffw_info_mip_first() - Retrieve the location of the first FW's MIP
  * @state:	NFP FW info state
  * @cpp_id:	Pointer to the CPP ID of the MIP
  * @off:	Pointer to the CPP Address of the MIP
  *
  * Return: 0, or -ERRNO
  */
 int nfp_nffw_info_mip_first(struct nfp_nffw_info *state, u32 *cpp_id, u64 *off)
 {
 	struct nffw_fwinfo *fwinfo;

 	fwinfo = nfp_nffw_info_fwid_first(state);
 	if (!fwinfo)
 		return -EINVAL;

 	*cpp_id = nffw_fwinfo_mip_cppid_get(fwinfo);
 	*off = nffw_fwinfo_mip_offset_get(fwinfo);

 	if (nffw_fwinfo_mip_mu_da_get(fwinfo)) {
 		int locality_off = nfp_cpp_mu_locality_lsb(state->cpp);

 		*off &= ~(NFP_MU_ADDR_ACCESS_TYPE_MASK << locality_off);
 		*off |= NFP_MU_ADDR_ACCESS_TYPE_DIRECT << locality_off;
 	}

 	return 0;
 }
	// SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause)
	/* Copyright (C) 2015-2018 Netronome Systems, Inc. */

	/*
	* nfp_nffw.c
	* Authors: Jakub Kicinski <jakub.kicinski@netronome.com>
	* Jason McMullan <jason.mcmullan@netronome.com>
	* Francois H. Theron <francois.theron@netronome.com>
	*/

	#include <linux/kernel.h>
	#include <linux/slab.h>

	#include "nfp.h"
	#include "nfp_cpp.h"
	#include "nfp_nffw.h"
	#include "nfp6000/nfp6000.h"

	/* Init-CSR owner IDs for firmware map to firmware IDs which start at 4.
	* Lower IDs are reserved for target and loader IDs.
	*/
	#define NFFW_FWID_EXT 3 /* For active MEs that we didn't load. */
	#define NFFW_FWID_BASE 4

	#define NFFW_FWID_ALL 255

	/**
	* NFFW_INFO_VERSION history:
	* 0: This was never actually used (before versioning), but it refers to
	* the previous struct which had FWINFO_CNT = MEINFO_CNT = 120 that later
	* changed to 200.
	* 1: First versioned struct, with
	* FWINFO_CNT = 120
	* MEINFO_CNT = 120
	* 2: FWINFO_CNT = 200
	* MEINFO_CNT = 200
	*/
	#define NFFW_INFO_VERSION_CURRENT 2

	/* Enough for all current chip families */
	#define NFFW_MEINFO_CNT_V1 120
	#define NFFW_FWINFO_CNT_V1 120
	#define NFFW_MEINFO_CNT_V2 200
	#define NFFW_FWINFO_CNT_V2 200

	/* Work in 32-bit words to make cross-platform endianness easier to handle */

	/ nfp.nffw meinfo /
	struct nffw_meinfo {
	__le32 ctxmask__fwid__meid;
	};

	struct nffw_fwinfo {
	__le32 loaded__mu_da__mip_off_hi;
	__le32 mip_cppid; /* 0 means no MIP */
	__le32 mip_offset_lo;
	};

	struct nfp_nffw_info_v1 {
	struct nffw_meinfo meinfo[NFFW_MEINFO_CNT_V1];
	struct nffw_fwinfo fwinfo[NFFW_FWINFO_CNT_V1];
	};

	struct nfp_nffw_info_v2 {
	struct nffw_meinfo meinfo[NFFW_MEINFO_CNT_V2];
	struct nffw_fwinfo fwinfo[NFFW_FWINFO_CNT_V2];
	};

	/ Resource: nfp.nffw main /
	struct nfp_nffw_info_data {
	__le32 flags[2];
	union {
	struct nfp_nffw_info_v1 v1;
	struct nfp_nffw_info_v2 v2;
	} info;
	};

	struct nfp_nffw_info {
	struct nfp_cpp *cpp;
	struct nfp_resource *res;

	struct nfp_nffw_info_data fwinf;
	};

	/* flg_info_version = flags[0]<27:16>
	* This is a small version counter intended only to detect if the current
	* implementation can read the current struct. Struct changes should be very
	* rare and as such a 12-bit counter should cover large spans of time. By the
	* time it wraps around, we don't expect to have 4096 versions of this struct
	* to be in use at the same time.
	*/
	static u32 nffw_res_info_version_get(const struct nfp_nffw_info_data *res)
	{
	return (le32_to_cpu(res->flags[0]) >> 16) & 0xfff;
	}

	/* flg_init = flags[0]<0> */
	static u32 nffw_res_flg_init_get(const struct nfp_nffw_info_data *res)
	{
	return (le32_to_cpu(res->flags[0]) >> 0) & 1;
	}

	/* loaded = loaded__mu_da__mip_off_hi<31:31> */
	static u32 nffw_fwinfo_loaded_get(const struct nffw_fwinfo *fi)
	{
	return (le32_to_cpu(fi->loaded__mu_da__mip_off_hi) >> 31) & 1;
	}

	/* mip_cppid = mip_cppid */
	static u32 nffw_fwinfo_mip_cppid_get(const struct nffw_fwinfo *fi)
	{
	return le32_to_cpu(fi->mip_cppid);
	}

	/* loaded = loaded__mu_da__mip_off_hi<8:8> */
	static u32 nffw_fwinfo_mip_mu_da_get(const struct nffw_fwinfo *fi)
	{
	return (le32_to_cpu(fi->loaded__mu_da__mip_off_hi) >> 8) & 1;
	}

	/* mip_offset = (loaded__mu_da__mip_off_hi<7:0> << 8) \| mip_offset_lo */
	static u64 nffw_fwinfo_mip_offset_get(const struct nffw_fwinfo *fi)
	{
	u64 mip_off_hi = le32_to_cpu(fi->loaded__mu_da__mip_off_hi);

	return (mip_off_hi & 0xFF) << 32 \| le32_to_cpu(fi->mip_offset_lo);
	}

	static unsigned int
	nffw_res_fwinfos(struct nfp_nffw_info_data fwinf, struct nffw_fwinfo *arr)
	{
	/* For the this code, version 0 is most likely to be
	* version 1 in this case. Since the kernel driver
	* does not take responsibility for initialising the
	* nfp.nffw resource, any previous code (CA firmware or
	* userspace) that left the version 0 and did set
	* the init flag is going to be version 1.
	*/
	switch (nffw_res_info_version_get(fwinf)) {
	case 0:
	case 1:
	*arr = &fwinf->info.v1.fwinfo[0];
	return NFFW_FWINFO_CNT_V1;
	case 2:
	*arr = &fwinf->info.v2.fwinfo[0];
	return NFFW_FWINFO_CNT_V2;
	default:
	*arr = NULL;
	return 0;
	}
	}

	/**
	* nfp_nffw_info_open() - Acquire the lock on the NFFW table
	* @cpp: NFP CPP handle
	*
	* Return: pointer to nfp_nffw_info object or ERR_PTR()
	*/
	struct nfp_nffw_info nfp_nffw_info_open(struct nfp_cpp cpp)
	{
	struct nfp_nffw_info_data *fwinf;
	struct nfp_nffw_info *state;
	u32 info_ver;
	int err;

	state = kzalloc(sizeof(*state), GFP_KERNEL);
	if (!state)
	return ERR_PTR(-ENOMEM);

	state->res = nfp_resource_acquire(cpp, NFP_RESOURCE_NFP_NFFW);
	if (IS_ERR(state->res))
	goto err_free;

	fwinf = &state->fwinf;

	if (sizeof(*fwinf) > nfp_resource_size(state->res))
	goto err_release;

	err = nfp_cpp_read(cpp, nfp_resource_cpp_id(state->res),
	nfp_resource_address(state->res),
	fwinf, sizeof(*fwinf));
	if (err < (int)sizeof(*fwinf))
	goto err_release;

	if (!nffw_res_flg_init_get(fwinf))
	goto err_release;

	info_ver = nffw_res_info_version_get(fwinf);
	if (info_ver > NFFW_INFO_VERSION_CURRENT)
	goto err_release;

	state->cpp = cpp;
	return state;

	err_release:
	nfp_resource_release(state->res);
	err_free:
	kfree(state);
	return ERR_PTR(-EIO);
	}

	/**
	* nfp_nffw_info_close() - Release the lock on the NFFW table and free state
	* @state: NFP FW info state
	*/
	void nfp_nffw_info_close(struct nfp_nffw_info *state)
	{
	nfp_resource_release(state->res);
	kfree(state);
	}

	/**
	* nfp_nffw_info_fwid_first() - Return the first firmware ID in the NFFW
	* @state: NFP FW info state
	*
	* Return: First NFFW firmware info, NULL on failure
	*/
	static struct nffw_fwinfo nfp_nffw_info_fwid_first(struct nfp_nffw_info state)
	{
	struct nffw_fwinfo *fwinfo;
	unsigned int cnt, i;

	cnt = nffw_res_fwinfos(&state->fwinf, &fwinfo);
	if (!cnt)
	return NULL;

	for (i = 0; i < cnt; i++)
	if (nffw_fwinfo_loaded_get(&fwinfo[i]))
	return &fwinfo[i];

	return NULL;
	}

	/**
	* nfp_nffw_info_mip_first() - Retrieve the location of the first FW's MIP
	* @state: NFP FW info state
	* @cpp_id: Pointer to the CPP ID of the MIP
	* @off: Pointer to the CPP Address of the MIP
	*
	* Return: 0, or -ERRNO
	*/
	int nfp_nffw_info_mip_first(struct nfp_nffw_info state, u32 cpp_id, u64 *off)
	{
	struct nffw_fwinfo *fwinfo;

	fwinfo = nfp_nffw_info_fwid_first(state);
	if (!fwinfo)
	return -EINVAL;

	*cpp_id = nffw_fwinfo_mip_cppid_get(fwinfo);
	*off = nffw_fwinfo_mip_offset_get(fwinfo);

	if (nffw_fwinfo_mip_mu_da_get(fwinfo)) {
	int locality_off = nfp_cpp_mu_locality_lsb(state->cpp);

	*off &= ~(NFP_MU_ADDR_ACCESS_TYPE_MASK << locality_off);
	*off \|= NFP_MU_ADDR_ACCESS_TYPE_DIRECT << locality_off;
	}

	return 0;
	}