src/include/imd.h - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-only */

 #ifndef _IMD_H_
 #define _IMD_H_

 #include <stdint.h>
 #include <stddef.h>

 /*
  * imd is an in-memory database/directory/datastore (whatever d word you
  * desire). It grows downwards in memory from provided upper limit and
  * root size. Each entry has a size alignment which is also provided by
  * the caller.
  *
  *             +----------------------+ <- upper_limit
  *    |   +----|   root pointer       |
  *    |   |    +----------------------+
  *    |   |    |                      |--------+
  *    |   +--->|   root block         |-----+  |
  *    |        +----------------------+-----|--|--- root_size
  *    |        |                      |     |  |
  *    |        |                      |     |  |
  *    |        |   alloc N            |<----+  |
  *    |        +----------------------+        |
  *    |        |                      |        |
  *    |        |                      |        |
  *   \|/       |   alloc N + 1        |<-------+
  *    v        +----------------------+
  *
  * The root_size in imd_create_empty() encompasses the root pointer
  * and root block. The root_size value, therefore, dictates the number
  * of allocations maintained by the imd.
  */

 /*
  * NOTE: This API has the following calling conventions: all functions
  * returning int supply 0 on success or < 0 on error.
  */

 struct imd_entry;
 struct imd;

 static const size_t LIMIT_ALIGN = 4096;

 /*
  * Initialize handle to use for working with an imd. Upper limit is the
  * exclusive address (aligned down to LIMIT_ALIGN) to start allocating down
  * from. This function needs to be called at least once before any other imd
  * related functions can be used.
  */
 void imd_handle_init(struct imd *imd, void *upper_limit);

 /*
  * Initialize a handle with a shallow recovery. This function doesn't
  * verify every entry, but it does set up the root pointer. Because of
  * this behavior it's not very safe. However, the current CBMEM constraints
  * demand having these semantics.
  */
 void imd_handle_init_partial_recovery(struct imd *imd);

 /*
  * Create an empty imd with a specified root_size and each entry is aligned to
  * the provided entry_align. As noted above the root size encompasses the
  * root pointer and root block leading to the number of imd entries being a
  * function of the root_size parameter. Please note, that one entry is allocated
  * for covering root region, thus caller should consider this calculating
  * root_size.
  */
 int imd_create_empty(struct imd *imd, size_t root_size, size_t entry_align);

 /*
  * Create an empty imd with both large and small allocations. The small
  * allocations come from a fixed imd stored internally within the large
  * imd. The region allocated for tracking the smaller allocations is dependent
  * on the small root_size and the large entry alignment by calculating the
  * number of entries within the small imd and multiplying that by the small
  * entry alignment.
  */
 int imd_create_tiered_empty(struct imd *imd,
 				size_t lg_root_size, size_t lg_entry_align,
 				size_t sm_root_size, size_t sm_entry_align);

 /*
  * Recover a previously created imd.
  */
 int imd_recover(struct imd *imd);

 /* Limit imd to provided max_size. */
 int imd_limit_size(struct imd *imd, size_t max_size);

 /* Lock down imd from further modifications. */
 int imd_lockdown(struct imd *imd);

 /* Fill in base address and size of region used by imd. */
 int imd_region_used(struct imd *imd, void **base, size_t *size);

 /* Add an entry to the imd. If id already exists NULL is returned. */
 const struct imd_entry *imd_entry_add(const struct imd *imd, uint32_t id,
 					size_t size);

 /* Locate an entry within the imd. NULL is returned when not found. */
 const struct imd_entry *imd_entry_find(const struct imd *imd, uint32_t id);

 /* Find an existing entry or add a new one. */
 const struct imd_entry *imd_entry_find_or_add(const struct imd *imd,
 						uint32_t id, size_t size);

 /* Returns size of entry. */
 size_t imd_entry_size(const struct imd_entry *entry);

 /* Returns pointer to region described by entry or NULL on failure. */
 void *imd_entry_at(const struct imd *imd, const struct imd_entry *entry);

 /* Returns id for the imd entry. */
 uint32_t imd_entry_id(const struct imd_entry *entry);

 /* Attempt to remove entry from imd. */
 int imd_entry_remove(const struct imd *imd, const struct imd_entry *entry);

 /* Print the entry information provided by lookup with the specified size. */
 struct imd_lookup {
 	uint32_t id;
 	const char *name;
 };

 int imd_print_entries(const struct imd *imd, const struct imd_lookup *lookup,
 			size_t size);

 struct imd_cursor;
 /* Initialize an imd_cursor object to walk the IMD entries. */
 int imd_cursor_init(const struct imd *imd, struct imd_cursor *cursor);

 /* Retrieve the next imd entry the cursor is referencing. Returns NULL when
  * no more entries exist. */
 const struct imd_entry *imd_cursor_next(struct imd_cursor *cursor);

 /*
  * The struct imd is a handle for working with an in-memory directory.
  *
  * NOTE: Do not directly touch any fields within this structure. An imd pointer
  * is meant to be opaque, but the fields are exposed for stack allocation.
  */
 struct imdr {
 	uintptr_t limit;
 	void *r;
 };
 struct imd {
 	struct imdr lg;
 	struct imdr sm;
 };

 struct imd_cursor {
 	size_t current_imdr;
 	size_t current_entry;
 	const struct imdr *imdr[2];
 };

 #endif /* _IMD_H_ */
	/* SPDX-License-Identifier: GPL-2.0-only */

	#ifndef _IMD_H_
	#define _IMD_H_

	#include <stdint.h>
	#include <stddef.h>

	/*
	* imd is an in-memory database/directory/datastore (whatever d word you
	* desire). It grows downwards in memory from provided upper limit and
	* root size. Each entry has a size alignment which is also provided by
	* the caller.
	*
	* +----------------------+ <- upper_limit
	* \| +----\| root pointer \|
	* \| \| +----------------------+
	* \| \| \| \|--------+
	* \| +--->\| root block \|-----+ \|
	* \| +----------------------+-----\|--\|--- root_size
	* \| \| \| \| \|
	* \| \| \| \| \|
	* \| \| alloc N \|<----+ \|
	* \| +----------------------+ \|
	* \| \| \| \|
	* \| \| \| \|
	* \\|/ \| alloc N + 1 \|<-------+
	* v +----------------------+
	*
	* The root_size in imd_create_empty() encompasses the root pointer
	* and root block. The root_size value, therefore, dictates the number
	* of allocations maintained by the imd.
	*/

	/*
	* NOTE: This API has the following calling conventions: all functions
	* returning int supply 0 on success or < 0 on error.
	*/

	struct imd_entry;
	struct imd;

	static const size_t LIMIT_ALIGN = 4096;

	/*
	* Initialize handle to use for working with an imd. Upper limit is the
	* exclusive address (aligned down to LIMIT_ALIGN) to start allocating down
	* from. This function needs to be called at least once before any other imd
	* related functions can be used.
	*/
	void imd_handle_init(struct imd imd, void upper_limit);

	/*
	* Initialize a handle with a shallow recovery. This function doesn't
	* verify every entry, but it does set up the root pointer. Because of
	* this behavior it's not very safe. However, the current CBMEM constraints
	* demand having these semantics.
	*/
	void imd_handle_init_partial_recovery(struct imd *imd);

	/*
	* Create an empty imd with a specified root_size and each entry is aligned to
	* the provided entry_align. As noted above the root size encompasses the
	* root pointer and root block leading to the number of imd entries being a
	* function of the root_size parameter. Please note, that one entry is allocated
	* for covering root region, thus caller should consider this calculating
	* root_size.
	*/
	int imd_create_empty(struct imd *imd, size_t root_size, size_t entry_align);

	/*
	* Create an empty imd with both large and small allocations. The small
	* allocations come from a fixed imd stored internally within the large
	* imd. The region allocated for tracking the smaller allocations is dependent
	* on the small root_size and the large entry alignment by calculating the
	* number of entries within the small imd and multiplying that by the small
	* entry alignment.
	*/
	int imd_create_tiered_empty(struct imd *imd,
	size_t lg_root_size, size_t lg_entry_align,
	size_t sm_root_size, size_t sm_entry_align);

	/*
	* Recover a previously created imd.
	*/
	int imd_recover(struct imd *imd);

	/* Limit imd to provided max_size. */
	int imd_limit_size(struct imd *imd, size_t max_size);

	/* Lock down imd from further modifications. */
	int imd_lockdown(struct imd *imd);

	/* Fill in base address and size of region used by imd. */
	int imd_region_used(struct imd imd, void base, size_t size);

	/* Add an entry to the imd. If id already exists NULL is returned. */
	const struct imd_entry imd_entry_add(const struct imd imd, uint32_t id,
	size_t size);

	/* Locate an entry within the imd. NULL is returned when not found. */
	const struct imd_entry imd_entry_find(const struct imd imd, uint32_t id);

	/* Find an existing entry or add a new one. */
	const struct imd_entry imd_entry_find_or_add(const struct imd imd,
	uint32_t id, size_t size);

	/* Returns size of entry. */
	size_t imd_entry_size(const struct imd_entry *entry);

	/* Returns pointer to region described by entry or NULL on failure. */
	void imd_entry_at(const struct imd imd, const struct imd_entry *entry);

	/* Returns id for the imd entry. */
	uint32_t imd_entry_id(const struct imd_entry *entry);

	/* Attempt to remove entry from imd. */
	int imd_entry_remove(const struct imd imd, const struct imd_entry entry);

	/* Print the entry information provided by lookup with the specified size. */
	struct imd_lookup {
	uint32_t id;
	const char *name;
	};

	int imd_print_entries(const struct imd imd, const struct imd_lookup lookup,
	size_t size);

	struct imd_cursor;
	/* Initialize an imd_cursor object to walk the IMD entries. */
	int imd_cursor_init(const struct imd imd, struct imd_cursor cursor);

	/* Retrieve the next imd entry the cursor is referencing. Returns NULL when
	* no more entries exist. */
	const struct imd_entry imd_cursor_next(struct imd_cursor cursor);

	/*
	* The struct imd is a handle for working with an in-memory directory.
	*
	* NOTE: Do not directly touch any fields within this structure. An imd pointer
	* is meant to be opaque, but the fields are exposed for stack allocation.
	*/
	struct imdr {
	uintptr_t limit;
	void *r;
	};
	struct imd {
	struct imdr lg;
	struct imdr sm;
	};

	struct imd_cursor {
	size_t current_imdr;
	size_t current_entry;
	const struct imdr *imdr[2];
	};

	#endif /* _IMD_H_ */