u-boot/include/dm/device.h

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/* SPDX-License-Identifier: GPL-2.0+ */
/*
* Copyright (c) 2013 Google, Inc
*
* (C) Copyright 2012
* Pavel Herrmann <morpheus.ibis@gmail.com>
* Marek Vasut <marex@denx.de>
*/
#ifndef _DM_DEVICE_H
#define _DM_DEVICE_H
#include <dm/ofnode.h>
#include <dm/uclass-id.h>
#include <fdtdec.h>
#include <linker_lists.h>
#include <linux/kernel.h>
#include <linux/list.h>
#include <linux/printk.h>
struct driver_info;
/* Driver is active (probed). Cleared when it is removed */
#define DM_FLAG_ACTIVATED (1 << 0)
/* DM is responsible for allocating and freeing plat */
#define DM_FLAG_ALLOC_PDATA (1 << 1)
/* DM should init this device prior to relocation */
#define DM_FLAG_PRE_RELOC (1 << 2)
/* DM is responsible for allocating and freeing parent_plat */
#define DM_FLAG_ALLOC_PARENT_PDATA (1 << 3)
/* DM is responsible for allocating and freeing uclass_plat */
#define DM_FLAG_ALLOC_UCLASS_PDATA (1 << 4)
/* Allocate driver private data on a DMA boundary */
#define DM_FLAG_ALLOC_PRIV_DMA (1 << 5)
/* Device is bound */
#define DM_FLAG_BOUND (1 << 6)
/* Device name is allocated and should be freed on unbind() */
#define DM_FLAG_NAME_ALLOCED (1 << 7)
/* Device has platform data provided by of-platdata */
dm: core: Expand platdata for of-platdata devices Devices which use of-platdata have their own platdata. However, in many cases the driver will have its own auto-alloced platdata, for use with the device tree. The ofdata_to_platdata() method converts the device tree settings to platdata. With of-platdata we would not normally allocate the platdata since it is provided by the U_BOOT_DEVICE() declaration. However this is inconvenient since the of-platdata struct is closely tied to the device tree properties. It is unlikely to exactly match the platdata needed by the driver. In fact a useful approach is to declare platdata in the driver like this: struct r3288_mmc_platdata { struct dtd_rockchip_rk3288_dw_mshc of_platdata; /* the 'normal' fields go here */ }; In this case we have dt_platadata available, but the normal fields are not present, since ofdata_to_platdata() is never called. In fact driver model doesn't allocate any space for the 'normal' fields, since it sees that there is already platform data attached to the device. To make this easier, adjust driver model to allocate the full size of the struct (i.e. platdata_auto_alloc_size from the driver) and copy in the of-platdata. This means that when the driver's bind() method is called, the of-platdata will be present, followed by zero bytes for the empty 'normal field' portion. A new DM_FLAG_OF_PLATDATA flag is available that indicates that the platdata came from of-platdata. When the allocation/copy happens, the DM_FLAG_ALLOC_PDATA flag will be set as well. The dtoc tool is updated to output the platdata_size field, since U-Boot has no other way of knowing the size of the of-platdata struct. Signed-off-by: Simon Glass <sjg@chromium.org>
2016-07-04 17:58:18 +00:00
#define DM_FLAG_OF_PLATDATA (1 << 8)
/*
* Call driver remove function to stop currently active DMA transfers or
* give DMA buffers back to the HW / controller. This may be needed for
* some drivers to do some final stage cleanup before the OS is called
* (U-Boot exit)
*/
#define DM_FLAG_ACTIVE_DMA (1 << 9)
/*
* Call driver remove function to do some final configuration, before
* U-Boot exits and the OS is started
*/
#define DM_FLAG_OS_PREPARE (1 << 10)
/* DM does not enable/disable the power domains corresponding to this device */
#define DM_FLAG_DEFAULT_PD_CTRL_OFF (1 << 11)
/* Driver plat has been read. Cleared when the device is removed */
#define DM_FLAG_PLATDATA_VALID (1 << 12)
/*
* Device is removed without switching off its power domain. This might
* be required, i. e. for serial console (debug) output when booting OS.
*/
#define DM_FLAG_LEAVE_PD_ON (1 << 13)
/*
* Device is vital to the operation of other devices. It is possible to remove
* removed this device after all regular devices are removed. This is useful
* e.g. for clock, which need to be active during the device-removal phase.
*/
#define DM_FLAG_VITAL (1 << 14)
/*
* One or multiple of these flags are passed to device_remove() so that
* a selective device removal as specified by the remove-stage and the
* driver flags can be done.
*
* DO NOT use these flags in your driver's @flags value...
* use the above DM_FLAG_... values instead
*/
enum {
/* Normal remove, remove all devices */
DM_REMOVE_NORMAL = 1 << 0,
/* Remove devices with active DMA */
DM_REMOVE_ACTIVE_DMA = DM_FLAG_ACTIVE_DMA,
/* Remove devices which need some final OS preparation steps */
DM_REMOVE_OS_PREPARE = DM_FLAG_OS_PREPARE,
/* Remove only devices that are not marked vital */
DM_REMOVE_NON_VITAL = DM_FLAG_VITAL,
/* Remove devices with any active flag */
DM_REMOVE_ACTIVE_ALL = DM_REMOVE_ACTIVE_DMA | DM_REMOVE_OS_PREPARE,
/* Don't power down any attached power domains */
DM_REMOVE_NO_PD = 1 << 1,
};
/**
* struct udevice - An instance of a driver
*
* This holds information about a device, which is a driver bound to a
* particular port or peripheral (essentially a driver instance).
*
* A device will come into existence through a 'bind' call, either due to
* a U_BOOT_DRVINFO() macro (in which case plat is non-NULL) or a node
* in the device tree (in which case of_offset is >= 0). In the latter case
* we translate the device tree information into plat in a function
* implemented by the driver of_to_plat method (called just before the
* probe method if the device has a device tree node.
*
* All three of plat, priv and uclass_priv can be allocated by the
* driver, or you can use the auto members of struct driver and
* struct uclass_driver to have driver model do this automatically.
*
* @driver: The driver used by this device
* @name: Name of device, typically the FDT node name
* @plat_: Configuration data for this device (do not access outside driver
* model)
* @parent_plat_: The parent bus's configuration data for this device (do not
* access outside driver model)
* @uclass_plat_: The uclass's configuration data for this device (do not access
* outside driver model)
* @driver_data: Driver data word for the entry that matched this device with
* its driver
* @parent: Parent of this device, or NULL for the top level device
* @priv_: Private data for this device (do not access outside driver model)
* @uclass: Pointer to uclass for this device
* @uclass_priv_: The uclass's private data for this device (do not access
* outside driver model)
* @parent_priv_: The parent's private data for this device (do not access
* outside driver model)
* @uclass_node: Used by uclass to link its devices
* @child_head: List of children of this device
* @sibling_node: Next device in list of all devices
* @flags_: Flags for this device `DM_FLAG_...` (do not access outside driver
* model)
* @seq_: Allocated sequence number for this device (-1 = none). This is set up
* when the device is bound and is unique within the device's uclass. If the
* device has an alias in the devicetree then that is used to set the sequence
* number. Otherwise, the next available number is used. Sequence numbers are
* used by certain commands that need device to be numbered (e.g. 'mmc dev').
* (do not access outside driver model)
* @node_: Reference to device tree node for this device (do not access outside
* driver model)
* @devres_head: List of memory allocations associated with this device.
* When CONFIG_DEVRES is enabled, devm_kmalloc() and friends will
* add to this list. Memory so-allocated will be freed
* automatically when the device is removed / unbound
* @dma_offset: Offset between the physical address space (CPU's) and the
* device's bus address space
*/
struct udevice {
const struct driver *driver;
const char *name;
void *plat_;
void *parent_plat_;
void *uclass_plat_;
ulong driver_data;
struct udevice *parent;
void *priv_;
struct uclass *uclass;
void *uclass_priv_;
void *parent_priv_;
struct list_head uclass_node;
struct list_head child_head;
struct list_head sibling_node;
#if !CONFIG_IS_ENABLED(OF_PLATDATA_RT)
u32 flags_;
#endif
int seq_;
#if CONFIG_IS_ENABLED(OF_REAL)
ofnode node_;
#endif
#ifdef CONFIG_DEVRES
devres: introduce Devres (Managed Device Resource) framework In U-Boot's driver model, memory is basically allocated and freed in the core framework. So, low level drivers generally only have to specify the size of needed memory with .priv_auto_alloc_size, .platdata_auto_alloc_size, etc. Nevertheless, some drivers still need to allocate/free memory on their own in case they cannot statically know the necessary memory size. So, I believe it is reasonable enough to port Devres into U-boot. Devres, which originates in Linux, manages device resources for each device and automatically releases them on driver detach. With devres, device resources are guaranteed to be freed whether initialization fails half-way or the device gets detached. The basic idea is totally the same to that of Linux, but I tweaked it a bit so that it fits in U-Boot's driver model. In U-Boot, drivers are activated in two steps: binding and probing. Binding puts a driver and a device together. It is just data manipulation on the system memory, so nothing has happened on the hardware device at this moment. When the device is really used, it is probed. Probing initializes the real hardware device to make it really ready for use. So, the resources acquired during the probing process must be freed when the device is removed. Likewise, what has been allocated in binding should be released when the device is unbound. The struct devres has a member "probe" to remember when the resource was allocated. CONFIG_DEBUG_DEVRES is also supported for easier debugging. If enabled, debug messages are printed each time a resource is allocated/freed. Signed-off-by: Masahiro Yamada <yamada.masahiro@socionext.com> Acked-by: Simon Glass <sjg@chromium.org>
2015-07-25 12:52:35 +00:00
struct list_head devres_head;
#endif
#if CONFIG_IS_ENABLED(DM_DMA)
ulong dma_offset;
#endif
};
/**
* struct udevice_rt - runtime information set up by U-Boot
*
* This is only used with OF_PLATDATA_RT
*
* There is one of these for every udevice in the linker list, indexed by
* the udevice_info idx value.
*
* @flags_: Flags for this device `DM_FLAG_...` (do not access outside driver
* model)
*/
struct udevice_rt {
u32 flags_;
};
mtd: spi: nor: force mtd name to "nor%d" Force the mtd name of spi-nor to "nor" + the driver sequence number: "nor0", "nor1"... beginning after the existing nor devices. This patch is coherent with existing "nand" and "spi-nand" mtd device names. When CFI MTD NOR device are supported, the spi-nor index is chosen after the last CFI device defined by CONFIG_SYS_MAX_FLASH_BANKS. When CONFIG_SYS_MAX_FLASH_BANKS_DETECT is activated, this config is replaced by to cfi_flash_num_flash_banks in the include file mtd/cfi_flash.h. This generic name "nor%d" can be use to identify the mtd spi-nor device without knowing the real device name or the DT path of the device, used with API get_mtd_device_nm() and is used in mtdparts command. This patch also avoids issue when the same NOR device is present 2 times, for example on STM32MP15F-EV1: STM32MP> mtd list SF: Detected mx66l51235l with page size 256 Bytes, erase size 64 KiB, \ total 64 MiB List of MTD devices: * nand0 - type: NAND flash - block size: 0x40000 bytes - min I/O: 0x1000 bytes - OOB size: 224 bytes - OOB available: 118 bytes - ECC strength: 8 bits - ECC step size: 512 bytes - bitflip threshold: 6 bits - 0x000000000000-0x000040000000 : "nand0" * mx66l51235l - device: mx66l51235l@0 - parent: spi@58003000 - driver: jedec_spi_nor - path: /soc/spi@58003000/mx66l51235l@0 - type: NOR flash - block size: 0x10000 bytes - min I/O: 0x1 bytes - 0x000000000000-0x000004000000 : "mx66l51235l" * mx66l51235l - device: mx66l51235l@1 - parent: spi@58003000 - driver: jedec_spi_nor - path: /soc/spi@58003000/mx66l51235l@1 - type: NOR flash - block size: 0x10000 bytes - min I/O: 0x1 bytes - 0x000000000000-0x000004000000 : "mx66l51235l" The same mtd name "mx66l51235l" identify the 2 instances mx66l51235l@0 and mx66l51235l@1. This patch fixes a ST32CubeProgrammer / stm32prog command issue with nor0 target on STM32MP157C-EV1 board introduced by commit b7f060565e31 ("mtd: spi-nor: allow registering multiple MTDs when DM is enabled"). Fixes: b7f060565e31 ("mtd: spi-nor: allow registering multiple MTDs when DM is enabled") Signed-off-by: Patrick Delaunay <patrick.delaunay@foss.st.com> [trini: Add <dm/device.h> to <mtd.h> for DM_MAX_SEQ_STR] Signed-off-by: Tom Rini <trini@konsulko.com>
2021-09-22 16:29:08 +00:00
/* Maximum sequence number supported and associated string length */
#define DM_MAX_SEQ 999
mtd: spi: nor: force mtd name to "nor%d" Force the mtd name of spi-nor to "nor" + the driver sequence number: "nor0", "nor1"... beginning after the existing nor devices. This patch is coherent with existing "nand" and "spi-nand" mtd device names. When CFI MTD NOR device are supported, the spi-nor index is chosen after the last CFI device defined by CONFIG_SYS_MAX_FLASH_BANKS. When CONFIG_SYS_MAX_FLASH_BANKS_DETECT is activated, this config is replaced by to cfi_flash_num_flash_banks in the include file mtd/cfi_flash.h. This generic name "nor%d" can be use to identify the mtd spi-nor device without knowing the real device name or the DT path of the device, used with API get_mtd_device_nm() and is used in mtdparts command. This patch also avoids issue when the same NOR device is present 2 times, for example on STM32MP15F-EV1: STM32MP> mtd list SF: Detected mx66l51235l with page size 256 Bytes, erase size 64 KiB, \ total 64 MiB List of MTD devices: * nand0 - type: NAND flash - block size: 0x40000 bytes - min I/O: 0x1000 bytes - OOB size: 224 bytes - OOB available: 118 bytes - ECC strength: 8 bits - ECC step size: 512 bytes - bitflip threshold: 6 bits - 0x000000000000-0x000040000000 : "nand0" * mx66l51235l - device: mx66l51235l@0 - parent: spi@58003000 - driver: jedec_spi_nor - path: /soc/spi@58003000/mx66l51235l@0 - type: NOR flash - block size: 0x10000 bytes - min I/O: 0x1 bytes - 0x000000000000-0x000004000000 : "mx66l51235l" * mx66l51235l - device: mx66l51235l@1 - parent: spi@58003000 - driver: jedec_spi_nor - path: /soc/spi@58003000/mx66l51235l@1 - type: NOR flash - block size: 0x10000 bytes - min I/O: 0x1 bytes - 0x000000000000-0x000004000000 : "mx66l51235l" The same mtd name "mx66l51235l" identify the 2 instances mx66l51235l@0 and mx66l51235l@1. This patch fixes a ST32CubeProgrammer / stm32prog command issue with nor0 target on STM32MP157C-EV1 board introduced by commit b7f060565e31 ("mtd: spi-nor: allow registering multiple MTDs when DM is enabled"). Fixes: b7f060565e31 ("mtd: spi-nor: allow registering multiple MTDs when DM is enabled") Signed-off-by: Patrick Delaunay <patrick.delaunay@foss.st.com> [trini: Add <dm/device.h> to <mtd.h> for DM_MAX_SEQ_STR] Signed-off-by: Tom Rini <trini@konsulko.com>
2021-09-22 16:29:08 +00:00
#define DM_MAX_SEQ_STR 3
/* Returns the operations for a device */
#define device_get_ops(dev) ((dev)->driver->ops)
#if CONFIG_IS_ENABLED(OF_PLATDATA_RT)
u32 dev_get_flags(const struct udevice *dev);
void dev_or_flags(const struct udevice *dev, u32 or);
void dev_bic_flags(const struct udevice *dev, u32 bic);
#else
static inline u32 dev_get_flags(const struct udevice *dev)
{
return dev->flags_;
}
static inline void dev_or_flags(struct udevice *dev, u32 or)
{
dev->flags_ |= or;
}
static inline void dev_bic_flags(struct udevice *dev, u32 bic)
{
dev->flags_ &= ~bic;
}
#endif /* OF_PLATDATA_RT */
/**
* dev_ofnode() - get the DT node reference associated with a udevice
*
* @dev: device to check
* Return: reference of the device's DT node
*/
static inline ofnode dev_ofnode(const struct udevice *dev)
{
#if CONFIG_IS_ENABLED(OF_REAL)
return dev->node_;
#else
return ofnode_null();
#endif
}
/* Returns non-zero if the device is active (probed and not removed) */
#define device_active(dev) (dev_get_flags(dev) & DM_FLAG_ACTIVATED)
#if CONFIG_IS_ENABLED(DM_DMA)
#define dev_set_dma_offset(_dev, _offset) _dev->dma_offset = _offset
#define dev_get_dma_offset(_dev) _dev->dma_offset
#else
#define dev_set_dma_offset(_dev, _offset)
#define dev_get_dma_offset(_dev) 0
#endif
static inline int dev_of_offset(const struct udevice *dev)
{
#if CONFIG_IS_ENABLED(OF_REAL)
return ofnode_to_offset(dev_ofnode(dev));
#else
return -1;
#endif
}
static inline bool dev_has_ofnode(const struct udevice *dev)
{
#if CONFIG_IS_ENABLED(OF_REAL)
return ofnode_valid(dev_ofnode(dev));
#else
return false;
#endif
}
static inline void dev_set_ofnode(struct udevice *dev, ofnode node)
{
#if CONFIG_IS_ENABLED(OF_REAL)
dev->node_ = node;
#endif
}
static inline int dev_seq(const struct udevice *dev)
{
return dev->seq_;
}
/**
* struct udevice_id - Lists the compatible strings supported by a driver
* @compatible: Compatible string
* @data: Data for this compatible string
*/
struct udevice_id {
const char *compatible;
ulong data;
};
#if CONFIG_IS_ENABLED(OF_REAL)
#define of_match_ptr(_ptr) (_ptr)
#else
#define of_match_ptr(_ptr) NULL
#endif /* CONFIG_IS_ENABLED(OF_CONTROL) */
/**
* struct driver - A driver for a feature or peripheral
*
* This holds methods for setting up a new device, and also removing it.
* The device needs information to set itself up - this is provided either
* by plat or a device tree node (which we find by looking up
* matching compatible strings with of_match).
*
* Drivers all belong to a uclass, representing a class of devices of the
* same type. Common elements of the drivers can be implemented in the uclass,
* or the uclass can provide a consistent interface to the drivers within
* it.
*
* @name: Device name
* @id: Identifies the uclass we belong to
* @of_match: List of compatible strings to match, and any identifying data
* for each.
* @bind: Called to bind a device to its driver
* @probe: Called to probe a device, i.e. activate it
* @remove: Called to remove a device, i.e. de-activate it
* @unbind: Called to unbind a device from its driver
* @of_to_plat: Called before probe to decode device tree data
* @child_post_bind: Called after a new child has been bound
* @child_pre_probe: Called before a child device is probed. The device has
* memory allocated but it has not yet been probed.
* @child_post_remove: Called after a child device is removed. The device
* has memory allocated but its device_remove() method has been called.
* @priv_auto: If non-zero this is the size of the private data
* to be allocated in the device's ->priv pointer. If zero, then the driver
* is responsible for allocating any data required.
* @plat_auto: If non-zero this is the size of the
* platform data to be allocated in the device's ->plat pointer.
* This is typically only useful for device-tree-aware drivers (those with
* an of_match), since drivers which use plat will have the data
* provided in the U_BOOT_DRVINFO() instantiation.
* @per_child_auto: Each device can hold private data owned by
* its parent. If required this will be automatically allocated if this
* value is non-zero.
* @per_child_plat_auto: A bus likes to store information about
* its children. If non-zero this is the size of this data, to be allocated
* in the child's parent_plat pointer.
* @ops: Driver-specific operations. This is typically a list of function
* pointers defined by the driver, to implement driver functions required by
* the uclass.
* @flags: driver flags - see `DM_FLAGS_...`
* @acpi_ops: Advanced Configuration and Power Interface (ACPI) operations,
* allowing the device to add things to the ACPI tables passed to Linux
*/
struct driver {
char *name;
enum uclass_id id;
const struct udevice_id *of_match;
int (*bind)(struct udevice *dev);
int (*probe)(struct udevice *dev);
int (*remove)(struct udevice *dev);
int (*unbind)(struct udevice *dev);
int (*of_to_plat)(struct udevice *dev);
int (*child_post_bind)(struct udevice *dev);
int (*child_pre_probe)(struct udevice *dev);
int (*child_post_remove)(struct udevice *dev);
int priv_auto;
int plat_auto;
int per_child_auto;
int per_child_plat_auto;
const void *ops; /* driver-specific operations */
uint32_t flags;
#if CONFIG_IS_ENABLED(ACPIGEN)
struct acpi_ops *acpi_ops;
#endif
};
/**
* U_BOOT_DRIVER() - Declare a new U-Boot driver
* @__name: name of the driver
*/
#define U_BOOT_DRIVER(__name) \
ll_entry_declare(struct driver, __name, driver)
/**
* DM_DRIVER_GET() - Get a pointer to a given driver
*
* This is useful in code for referencing a driver at build time.
* Before this is used, an extern U_BOOT_DRIVER() must have been
* declared.
*
* @__name: Name of the driver. This must be a valid C identifier,
* used by the linker_list
* Return: struct driver * for the driver
*/
#define DM_DRIVER_GET(__name) \
ll_entry_get(struct driver, __name, driver)
/**
* DM_DRIVER_REF() - Get a reference to a driver
*
* This is useful in data structures and code for referencing a driver at
* build time. Before this is used, an extern U_BOOT_DRIVER() must have been
* declared.
* This is like DM_DRIVER_GET, but without the extra code, so it is suitable
* for putting into data structures.
*
* For example::
*
* extern U_BOOT_DRIVER(sandbox_fixed_clock);
* struct driver *drvs[] = {
* DM_DRIVER_REF(sandbox_fixed_clock),
* };
*
* @_name: Name of the driver. This must be a valid C identifier,
* used by the linker_list
* Return: struct driver * for the driver
*/
#define DM_DRIVER_REF(_name) \
ll_entry_ref(struct driver, _name, driver)
/**
* DM_DRIVER_ALIAS() - Declare a macro to state an alias for a driver name
*
* This macro will produce no code but its information will be parsed by tools
* like dtoc
*
* @__name: name of driver
* @__alias: alias for the driver name
*/
#define DM_DRIVER_ALIAS(__name, __alias)
/**
* DM_PHASE() - Declare a macro to indicate which phase of U-Boot this driver is for.
*
* This macro produces no code but its information will be parsed by dtoc. The
* macro can be only be used once in a driver. Put it within the U_BOOT_DRIVER()
* declaration, e.g.::
*
* U_BOOT_DRIVER(cpu) = {
* .name = ...
* ...
* DM_PHASE(tpl)
* };
*
* @_phase: Associated phase of U-Boot ("spl", "tpl")
*/
#define DM_PHASE(_phase)
/**
* DM_HEADER() - Declare a macro to declare a header needed for a driver.
*
* Often the correct header can be found automatically, but only for struct
* declarations. For enums and #defines used in the driver declaration and
* declared in a different header from the structs, this macro must be used.
*
* This macro produces no code but its information will be parsed by dtoc. The
* macro can be used multiple times with different headers, for the same driver.
* Put it within the U_BOOT_DRIVER() declaration, e.g.::
*
* U_BOOT_DRIVER(cpu) = {
* .name = ...
* ...
* DM_HEADER(<asm/cpu.h>)
* };
*
* @_hdr: header needed for a driver
*/
#define DM_HEADER(_hdr)
/**
* dev_get_plat() - Get the platform data for a device
*
* This checks that dev is not NULL, but no other checks for now
*
* @dev: Device to check
* Return: platform data, or NULL if none
*/
void *dev_get_plat(const struct udevice *dev);
/**
* dev_get_parent_plat() - Get the parent platform data for a device
*
* This checks that dev is not NULL, but no other checks for now
*
* @dev: Device to check
* Return: parent's platform data, or NULL if none
*/
void *dev_get_parent_plat(const struct udevice *dev);
/**
* dev_get_uclass_plat() - Get the uclass platform data for a device
*
* This checks that dev is not NULL, but no other checks for now
*
* @dev: Device to check
* Return: uclass's platform data, or NULL if none
*/
void *dev_get_uclass_plat(const struct udevice *dev);
/**
* dev_get_priv() - Get the private data for a device
*
* This checks that dev is not NULL, but no other checks for now
*
* @dev: Device to check
* Return: private data, or NULL if none
*/
void *dev_get_priv(const struct udevice *dev);
/**
* dev_get_parent_priv() - Get the parent private data for a device
*
* The parent private data is data stored in the device but owned by the
* parent. For example, a USB device may have parent data which contains
* information about how to talk to the device over USB.
*
* This checks that dev is not NULL, but no other checks for now
*
* @dev: Device to check
* Return: parent data, or NULL if none
*/
void *dev_get_parent_priv(const struct udevice *dev);
/**
* dev_get_uclass_priv() - Get the private uclass data for a device
*
* This checks that dev is not NULL, but no other checks for now
*
* @dev: Device to check
* Return: private uclass data for this device, or NULL if none
*/
void *dev_get_uclass_priv(const struct udevice *dev);
/**
* dev_get_parent() - Get the parent of a device
*
* @child: Child to check
* Return: parent of child, or NULL if this is the root device
*/
struct udevice *dev_get_parent(const struct udevice *child);
/**
* dev_get_driver_data() - get the driver data used to bind a device
*
* When a device is bound using a device tree node, it matches a
* particular compatible string in struct udevice_id. This function
* returns the associated data value for that compatible string. This is
* the 'data' field in struct udevice_id.
*
* As an example, consider this structure::
*
* static const struct udevice_id tegra_i2c_ids[] = {
* { .compatible = "nvidia,tegra114-i2c", .data = TYPE_114 },
* { .compatible = "nvidia,tegra20-i2c", .data = TYPE_STD },
* { .compatible = "nvidia,tegra20-i2c-dvc", .data = TYPE_DVC },
* { }
* };
*
* When driver model finds a driver for this it will store the 'data' value
* corresponding to the compatible string it matches. This function returns
* that value. This allows the driver to handle several variants of a device.
*
* For USB devices, this is the driver_info field in struct usb_device_id.
*
* @dev: Device to check
* Return: driver data (0 if none is provided)
*/
ulong dev_get_driver_data(const struct udevice *dev);
/**
* dev_get_driver_ops() - get the device's driver's operations
*
* This checks that dev is not NULL, and returns the pointer to device's
* driver's operations.
*
* @dev: Device to check
* Return: void pointer to driver's operations or NULL for NULL-dev or NULL-ops
*/
const void *dev_get_driver_ops(const struct udevice *dev);
/**
* device_get_uclass_id() - return the uclass ID of a device
*
* @dev: Device to check
* Return: uclass ID for the device
*/
enum uclass_id device_get_uclass_id(const struct udevice *dev);
/**
* dev_get_uclass_name() - return the uclass name of a device
*
* This checks that dev is not NULL.
*
* @dev: Device to check
* Return: pointer to the uclass name for the device
*/
const char *dev_get_uclass_name(const struct udevice *dev);
/**
* device_get_child() - Get the child of a device by index
*
* Returns the numbered child, 0 being the first. This does not use
* sequence numbers, only the natural order.
*
* @parent: Parent device to check
* @index: Child index
* @devp: Returns pointer to device
* Return:
* 0 if OK, -ENODEV if no such device, other error if the device fails to probe
*/
int device_get_child(const struct udevice *parent, int index,
struct udevice **devp);
/**
* device_get_child_count() - Get the child count of a device
*
* Returns the number of children to a device.
*
* @parent: Parent device to check
*/
int device_get_child_count(const struct udevice *parent);
/**
* device_get_decendent_count() - Get the total number of decendents of a device
*
* Returns the total number of decendents, including all children
*
* @parent: Parent device to check
*/
int device_get_decendent_count(const struct udevice *parent);
/**
* device_find_child_by_seq() - Find a child device based on a sequence
*
* This searches for a device with the given seq.
*
* @parent: Parent device
* @seq: Sequence number to find (0=first)
* @devp: Returns pointer to device (there is only one per for each seq).
* Set to NULL if none is found
* Return: 0 if OK, -ENODEV if not found
*/
int device_find_child_by_seq(const struct udevice *parent, int seq,
struct udevice **devp);
/**
* device_get_child_by_seq() - Get a child device based on a sequence
*
* If an active device has this sequence it will be returned. If there is no
* such device then this will check for a device that is requesting this
* sequence.
*
* The device is probed to activate it ready for use.
*
* @parent: Parent device
* @seq: Sequence number to find (0=first)
* @devp: Returns pointer to device (there is only one per for each seq)
* Set to NULL if none is found
* Return: 0 if OK, -ve on error
*/
int device_get_child_by_seq(const struct udevice *parent, int seq,
struct udevice **devp);
/**
* device_find_child_by_of_offset() - Find a child device based on FDT offset
*
* Locates a child device by its device tree offset.
*
* @parent: Parent device
* @of_offset: Device tree offset to find
* @devp: Returns pointer to device if found, otherwise this is set to NULL
* Return: 0 if OK, -ve on error
*/
int device_find_child_by_of_offset(const struct udevice *parent, int of_offset,
struct udevice **devp);
/**
* device_get_child_by_of_offset() - Get a child device based on FDT offset
*
* Locates a child device by its device tree offset.
*
* The device is probed to activate it ready for use.
*
* @parent: Parent device
* @of_offset: Device tree offset to find
* @devp: Returns pointer to device if found, otherwise this is set to NULL
* Return: 0 if OK, -ve on error
*/
int device_get_child_by_of_offset(const struct udevice *parent, int of_offset,
struct udevice **devp);
/**
* device_find_global_by_ofnode() - Get a device based on ofnode
*
* Locates a device by its device tree ofnode, searching globally throughout
* the all driver model devices.
*
* The device is NOT probed
*
* @node: Device tree ofnode to find
* @devp: Returns pointer to device if found, otherwise this is set to NULL
* Return: 0 if OK, -ve on error
*/
int device_find_global_by_ofnode(ofnode node, struct udevice **devp);
/**
* device_get_global_by_ofnode() - Get a device based on ofnode
*
* Locates a device by its device tree ofnode, searching globally throughout
* the all driver model devices.
*
* The device is probed to activate it ready for use.
*
* @node: Device tree ofnode to find
* @devp: Returns pointer to device if found, otherwise this is set to NULL
* Return: 0 if OK, -ve on error
*/
int device_get_global_by_ofnode(ofnode node, struct udevice **devp);
/**
* device_get_by_ofplat_idx() - Get a device based on of-platdata index
*
* Locates a device by either its struct driver_info index, or its
* struct udevice index. The latter is used with OF_PLATDATA_INST, since we have
* a list of build-time instantiated struct udevice records, The former is used
* with !OF_PLATDATA_INST since in that case we have a list of
* struct driver_info records.
*
* The index number is written into the idx field of struct phandle_1_arg, etc.
* It is the position of this driver_info/udevice in its linker list.
*
* The device is probed to activate it ready for use.
*
* @idx: Index number of the driver_info/udevice structure (0=first)
* @devp: Returns pointer to device if found, otherwise this is set to NULL
* Return: 0 if OK, -ve on error
*/
int device_get_by_ofplat_idx(uint idx, struct udevice **devp);
/**
* device_find_first_child() - Find the first child of a device
*
* @parent: Parent device to search
* @devp: Returns first child device, or NULL if none
* Return: 0
*/
int device_find_first_child(const struct udevice *parent,
struct udevice **devp);
/**
* device_find_next_child() - Find the next child of a device
*
* @devp: Pointer to previous child device on entry. Returns pointer to next
* child device, or NULL if none
* Return: 0
*/
int device_find_next_child(struct udevice **devp);
/**
* device_find_first_inactive_child() - Find the first inactive child
*
* This is used to locate an existing child of a device which is of a given
* uclass.
*
* The device is NOT probed
*
* @parent: Parent device to search
* @uclass_id: Uclass to look for
* @devp: Returns device found, if any, else NULL
* Return: 0 if found, else -ENODEV
*/
int device_find_first_inactive_child(const struct udevice *parent,
enum uclass_id uclass_id,
struct udevice **devp);
/**
* device_find_first_child_by_uclass() - Find the first child of a device in uc
*
* @parent: Parent device to search
* @uclass_id: Uclass to look for
* @devp: Returns first child device in that uclass, if any, else NULL
* Return: 0 if found, else -ENODEV
*/
int device_find_first_child_by_uclass(const struct udevice *parent,
enum uclass_id uclass_id,
struct udevice **devp);
/**
* device_find_child_by_name() - Find a child by device name
*
* @parent: Parent device to search
* @name: Name to look for
* @len: Length of the name
* @devp: Returns device found, if any
* Return: 0 if found, else -ENODEV
*/
int device_find_child_by_namelen(const struct udevice *parent, const char *name,
int len, struct udevice **devp);
/**
* device_find_child_by_name() - Find a child by device name
*
* @parent: Parent device to search
* @name: Name to look for
* @devp: Returns device found, if any
* Return: 0 if found, else -ENODEV
*/
int device_find_child_by_name(const struct udevice *parent, const char *name,
struct udevice **devp);
/**
* device_first_child_ofdata_err() - Find the first child and reads its plat
*
* The of_to_plat() method is called on the child before it is returned,
* but the child is not probed.
*
* @parent: Parent to check
* @devp: Returns child that was found, if any
* Return: 0 on success, -ENODEV if no children, other -ve on error
*/
int device_first_child_ofdata_err(struct udevice *parent,
struct udevice **devp);
/*
* device_next_child_ofdata_err() - Find the next child and read its plat
*
* The of_to_plat() method is called on the child before it is returned,
* but the child is not probed.
*
* @devp: On entry, points to the previous child; on exit returns the child that
* was found, if any
* Return: 0 on success, -ENODEV if no children, other -ve on error
*/
int device_next_child_ofdata_err(struct udevice **devp);
/**
* device_first_child_err() - Get the first child of a device
*
* The device returned is probed if necessary, and ready for use
*
* @parent: Parent device to search
* @devp: Returns device found, if any
* Return: 0 if found, -ENODEV if not, -ve error if device failed to probe
*/
int device_first_child_err(struct udevice *parent, struct udevice **devp);
/**
* device_next_child_err() - Get the next child of a parent device
*
* The device returned is probed if necessary, and ready for use
*
* @devp: On entry, pointer to device to lookup. On exit, returns pointer
* to the next sibling if no error occurred
* Return: 0 if found, -ENODEV if not, -ve error if device failed to probe
*/
int device_next_child_err(struct udevice **devp);
/**
* device_has_children() - check if a device has any children
*
* @dev: Device to check
* Return: true if the device has one or more children
*/
bool device_has_children(const struct udevice *dev);
/**
* device_has_active_children() - check if a device has any active children
*
* @dev: Device to check
* Return: true if the device has one or more children and at least one of
* them is active (probed).
*/
bool device_has_active_children(const struct udevice *dev);
/**
* device_is_last_sibling() - check if a device is the last sibling
*
* This function can be useful for display purposes, when special action needs
* to be taken when displaying the last sibling. This can happen when a tree
* view of devices is being displayed.
*
* @dev: Device to check
* Return: true if there are no more siblings after this one - i.e. is it
* last in the list.
*/
bool device_is_last_sibling(const struct udevice *dev);
/**
* device_set_name() - set the name of a device
*
* This must be called in the device's bind() method and no later. Normally
* this is unnecessary but for probed devices which don't get a useful name
* this function can be helpful.
*
* The name is allocated and will be freed automatically when the device is
* unbound.
*
* @dev: Device to update
* @name: New name (this string is allocated new memory and attached to
* the device)
* Return: 0 if OK, -ENOMEM if there is not enough memory to allocate the
* string
*/
int device_set_name(struct udevice *dev, const char *name);
/**
* device_set_name_alloced() - note that a device name is allocated
*
* This sets the DM_FLAG_NAME_ALLOCED flag for the device, so that when it is
* unbound the name will be freed. This avoids memory leaks.
*
* @dev: Device to update
*/
void device_set_name_alloced(struct udevice *dev);
/**
* device_is_compatible() - check if the device is compatible with the compat
*
* This allows to check whether the device is comaptible with the compat.
*
* @dev: udevice pointer for which compatible needs to be verified.
* @compat: Compatible string which needs to verified in the given
* device
* Return: true if OK, false if the compatible is not found
*/
bool device_is_compatible(const struct udevice *dev, const char *compat);
/**
* of_machine_is_compatible() - check if the machine is compatible with
* the compat
*
* This allows to check whether the machine is comaptible with the compat.
*
* @compat: Compatible string which needs to verified
* Return: true if OK, false if the compatible is not found
*/
bool of_machine_is_compatible(const char *compat);
/**
* dev_disable_by_path() - Disable a device given its device tree path
*
* @path: The device tree path identifying the device to be disabled
* Return: 0 on success, -ve on error
*/
int dev_disable_by_path(const char *path);
/**
* dev_enable_by_path() - Enable a device given its device tree path
*
* @path: The device tree path identifying the device to be enabled
* Return: 0 on success, -ve on error
*/
int dev_enable_by_path(const char *path);
/**
* device_is_on_pci_bus - Test if a device is on a PCI bus
*
* @dev: device to test
* Return: true if it is on a PCI bus, false otherwise
*/
static inline bool device_is_on_pci_bus(const struct udevice *dev)
{
return dev->parent && device_get_uclass_id(dev->parent) == UCLASS_PCI;
}
/**
* device_foreach_child_safe() - iterate through child devices safely
*
* This allows the @pos child to be removed in the loop if required.
*
* @pos: struct udevice * for the current device
* @next: struct udevice * for the next device
* @parent: parent device to scan
*/
#define device_foreach_child_safe(pos, next, parent) \
list_for_each_entry_safe(pos, next, &parent->child_head, sibling_node)
/**
* device_foreach_child() - iterate through child devices
*
* @pos: struct udevice * for the current device
* @parent: parent device to scan
*/
#define device_foreach_child(pos, parent) \
list_for_each_entry(pos, &parent->child_head, sibling_node)
/**
* device_foreach_child_of_to_plat() - iterate through children
*
* This stops when it gets an error, with @pos set to the device that failed to
* read ofdata.
*
* This creates a for() loop which works through the available children of
* a device in order from start to end. Device ofdata is read by calling
* device_of_to_plat() on each one. The devices are not probed.
*
* @pos: struct udevice * for the current device
* @parent: parent device to scan
*/
#define device_foreach_child_of_to_plat(pos, parent) \
for (int _ret = device_first_child_ofdata_err(parent, &pos); !_ret; \
_ret = device_next_child_ofdata_err(&pos))
/**
* device_foreach_child_probe() - iterate through children, probing them
*
* This creates a for() loop which works through the available children of
* a device in order from start to end. Devices are probed if necessary,
* and ready for use.
*
* This stops when it gets an error, with @pos set to the device that failed to
* probe
*
* @pos: struct udevice * for the current device
* @parent: parent device to scan
*/
#define device_foreach_child_probe(pos, parent) \
for (int _ret = device_first_child_err(parent, &pos); !_ret; \
_ret = device_next_child_err(&pos))
/**
* dm_scan_fdt_dev() - Bind child device in the device tree
*
* This handles device which have sub-nodes in the device tree. It scans all
* sub-nodes and binds drivers for each node where a driver can be found.
*
* If this is called prior to relocation, only pre-relocation devices will be
* bound (those marked with u-boot,dm-pre-reloc in the device tree, or where
* the driver has the DM_FLAG_PRE_RELOC flag set). Otherwise, all devices will
* be bound.
*
* @dev: Device to scan
* Return: 0 if OK, -ve on error
*/
int dm_scan_fdt_dev(struct udevice *dev);
#endif