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1 #ifndef __LINUX_REGMAP_H
2 #define __LINUX_REGMAP_H
4 /*
5 * Register map access API
6 *
7 * Copyright 2011 Wolfson Microelectronics plc
8 *
9 * Author: Mark Brown <broonie@opensource.wolfsonmicro.com>
10 *
11 * This program is free software; you can redistribute it and/or modify
12 * it under the terms of the GNU General Public License version 2 as
13 * published by the Free Software Foundation.
14 */
16 #include <linux/list.h>
17 #include <linux/rbtree.h>
18 #include <linux/err.h>
19 #include <linux/bug.h>
32 /* An enum of all the supported cache types */
34 REGCACHE_NONE,
35 REGCACHE_RBTREE,
36 REGCACHE_COMPRESSED,
37 REGCACHE_FLAT,
38 };
40 /**
41 * Default value for a register. We use an array of structs rather
42 * than a simple array as many modern devices have very sparse
43 * register maps.
44 *
45 * @reg: Register address.
46 * @def: Register default value.
47 */
51 };
53 #ifdef CONFIG_REGMAP
56 /* Unspecified -> 0 -> Backwards compatible default */
58 REGMAP_ENDIAN_BIG,
59 REGMAP_ENDIAN_LITTLE,
60 REGMAP_ENDIAN_NATIVE,
61 };
63 /**
64 * A register range, used for access related checks
65 * (readable/writeable/volatile/precious checks)
66 *
67 * @range_min: address of first register
68 * @range_max: address of last register
69 */
73 };
75 #define regmap_reg_range(low, high) { .range_min = low, .range_max = high, }
77 /*
78 * A table of ranges including some yes ranges and some no ranges.
79 * If a register belongs to a no_range, the corresponding check function
80 * will return false. If a register belongs to a yes range, the corresponding
81 * check function will return true. "no_ranges" are searched first.
82 *
83 * @yes_ranges : pointer to an array of regmap ranges used as "yes ranges"
84 * @n_yes_ranges: size of the above array
85 * @no_ranges: pointer to an array of regmap ranges used as "no ranges"
86 * @n_no_ranges: size of the above array
87 */
93 };
98 /**
99 * Configuration for the register map of a device.
100 *
101 * @name: Optional name of the regmap. Useful when a device has multiple
102 * register regions.
103 *
104 * @reg_bits: Number of bits in a register address, mandatory.
105 * @reg_stride: The register address stride. Valid register addresses are a
106 * multiple of this value. If set to 0, a value of 1 will be
107 * used.
108 * @pad_bits: Number of bits of padding between register and value.
109 * @val_bits: Number of bits in a register value, mandatory.
110 *
111 * @writeable_reg: Optional callback returning true if the register
112 * can be written to. If this field is NULL but wr_table
113 * (see below) is not, the check is performed on such table
114 * (a register is writeable if it belongs to one of the ranges
115 * specified by wr_table).
116 * @readable_reg: Optional callback returning true if the register
117 * can be read from. If this field is NULL but rd_table
118 * (see below) is not, the check is performed on such table
119 * (a register is readable if it belongs to one of the ranges
120 * specified by rd_table).
121 * @volatile_reg: Optional callback returning true if the register
122 * value can't be cached. If this field is NULL but
123 * volatile_table (see below) is not, the check is performed on
124 * such table (a register is volatile if it belongs to one of
125 * the ranges specified by volatile_table).
126 * @precious_reg: Optional callback returning true if the register
127 * should not be read outside of a call from the driver
128 * (e.g., a clear on read interrupt status register). If this
129 * field is NULL but precious_table (see below) is not, the
130 * check is performed on such table (a register is precious if
131 * it belongs to one of the ranges specified by precious_table).
132 * @lock: Optional lock callback (overrides regmap's default lock
133 * function, based on spinlock or mutex).
134 * @unlock: As above for unlocking.
135 * @lock_arg: this field is passed as the only argument of lock/unlock
136 * functions (ignored in case regular lock/unlock functions
137 * are not overridden).
138 * @reg_read: Optional callback that if filled will be used to perform
139 * all the reads from the registers. Should only be provided for
140 * devices whose read operation cannot be represented as a simple
141 * read operation on a bus such as SPI, I2C, etc. Most of the
142 * devices do not need this.
143 * @reg_write: Same as above for writing.
144 * @fast_io: Register IO is fast. Use a spinlock instead of a mutex
145 * to perform locking. This field is ignored if custom lock/unlock
146 * functions are used (see fields lock/unlock of struct regmap_config).
147 * This field is a duplicate of a similar file in
148 * 'struct regmap_bus' and serves exact same purpose.
149 * Use it only for "no-bus" cases.
150 * @max_register: Optional, specifies the maximum valid register index.
151 * @wr_table: Optional, points to a struct regmap_access_table specifying
152 * valid ranges for write access.
153 * @rd_table: As above, for read access.
154 * @volatile_table: As above, for volatile registers.
155 * @precious_table: As above, for precious registers.
156 * @reg_defaults: Power on reset values for registers (for use with
157 * register cache support).
158 * @num_reg_defaults: Number of elements in reg_defaults.
159 *
160 * @read_flag_mask: Mask to be set in the top byte of the register when doing
161 * a read.
162 * @write_flag_mask: Mask to be set in the top byte of the register when doing
163 * a write. If both read_flag_mask and write_flag_mask are
164 * empty the regmap_bus default masks are used.
165 * @use_single_rw: If set, converts the bulk read and write operations into
166 * a series of single read and write operations. This is useful
167 * for device that does not support bulk read and write.
168 * @can_multi_write: If set, the device supports the multi write mode of bulk
169 * write operations, if clear multi write requests will be
170 * split into individual write operations
171 *
172 * @cache_type: The actual cache type.
173 * @reg_defaults_raw: Power on reset values for registers (for use with
174 * register cache support).
175 * @num_reg_defaults_raw: Number of elements in reg_defaults_raw.
176 * @reg_format_endian: Endianness for formatted register addresses. If this is
177 * DEFAULT, the @reg_format_endian_default value from the
178 * regmap bus is used.
179 * @val_format_endian: Endianness for formatted register values. If this is
180 * DEFAULT, the @reg_format_endian_default value from the
181 * regmap bus is used.
182 *
183 * @ranges: Array of configuration entries for virtual address ranges.
184 * @num_ranges: Number of range configuration entries.
185 */
198 regmap_lock lock;
199 regmap_unlock unlock;
218 u8 read_flag_mask;
219 u8 write_flag_mask;
229 };
231 /**
232 * Configuration for indirectly accessed or paged registers.
233 * Registers, mapped to this virtual range, are accessed in two steps:
234 * 1. page selector register update;
235 * 2. access through data window registers.
236 *
237 * @name: Descriptive name for diagnostics
238 *
239 * @range_min: Address of the lowest register address in virtual range.
240 * @range_max: Address of the highest register in virtual range.
241 *
242 * @page_sel_reg: Register with selector field.
243 * @page_sel_mask: Bit shift for selector value.
244 * @page_sel_shift: Bit mask for selector value.
245 *
246 * @window_start: Address of first (lowest) register in data window.
247 * @window_len: Number of registers in data window.
248 */
252 /* Registers of virtual address range */
256 /* Page selector for indirect addressing */
261 /* Data window (per each page) */
264 };
287 /**
288 * Description of a hardware bus for the register map infrastructure.
289 *
290 * @fast_io: Register IO is fast. Use a spinlock instead of a mutex
291 * to perform locking. This field is ignored if custom lock/unlock
292 * functions are used (see fields lock/unlock of
293 * struct regmap_config).
294 * @write: Write operation.
295 * @gather_write: Write operation with split register/value, return -ENOTSUPP
296 * if not implemented on a given device.
297 * @async_write: Write operation which completes asynchronously, optional and
298 * must serialise with respect to non-async I/O.
299 * @read: Read operation. Data is returned in the buffer used to transmit
300 * data.
301 * @async_alloc: Allocate a regmap_async() structure.
302 * @read_flag_mask: Mask to be set in the top byte of the register when doing
303 * a read.
304 * @reg_format_endian_default: Default endianness for formatted register
305 * addresses. Used when the regmap_config specifies DEFAULT. If this is
306 * DEFAULT, BIG is assumed.
307 * @val_format_endian_default: Default endianness for formatted register
308 * values. Used when the regmap_config specifies DEFAULT. If this is
309 * DEFAULT, BIG is assumed.
310 * @async_size: Size of struct used for async work.
311 */
314 regmap_hw_write write;
315 regmap_hw_gather_write gather_write;
316 regmap_hw_async_write async_write;
317 regmap_hw_reg_write reg_write;
318 regmap_hw_read read;
319 regmap_hw_reg_read reg_read;
320 regmap_hw_free_context free_context;
321 regmap_hw_async_alloc async_alloc;
322 u8 read_flag_mask;
325 };
367 /**
368 * regmap_init_mmio(): Initialise register map
369 *
370 * @dev: Device that will be interacted with
371 * @regs: Pointer to memory-mapped IO region
372 * @config: Configuration for register map
373 *
374 * The return value will be an ERR_PTR() on error or a valid pointer to
375 * a struct regmap.
376 */
380 {
382 }
384 /**
385 * devm_regmap_init_mmio(): Initialise managed register map
386 *
387 * @dev: Device that will be interacted with
388 * @regs: Pointer to memory-mapped IO region
389 * @config: Configuration for register map
390 *
391 * The return value will be an ERR_PTR() on error or a valid pointer
392 * to a struct regmap. The regmap will be automatically freed by the
393 * device management code.
394 */
398 {
400 }
458 {
460 }
466 /**
467 * Description of an register field
468 *
469 * @reg: Offset of the register within the regmap bank
470 * @lsb: lsb of the register field.
471 * @msb: msb of the register field.
472 * @id_size: port size if it has some ports
473 * @id_offset: address offset for each ports
474 */
481 };
483 #define REG_FIELD(_reg, _lsb, _msb) { \
484 .reg = _reg, \
485 .lsb = _lsb, \
486 .msb = _msb, \
487 }
509 /**
510 * Description of an IRQ for the generic regmap irq_chip.
511 *
512 * @reg_offset: Offset of the status/mask register within the bank
513 * @mask: Mask used to flag/control the register.
514 */
518 };
520 /**
521 * Description of a generic regmap irq_chip. This is not intended to
522 * handle every possible interrupt controller, but it should handle a
523 * substantial proportion of those that are found in the wild.
524 *
525 * @name: Descriptive name for IRQ controller.
526 *
527 * @status_base: Base status register address.
528 * @mask_base: Base mask register address.
529 * @ack_base: Base ack address. If zero then the chip is clear on read.
530 * Using zero value is possible with @use_ack bit.
531 * @wake_base: Base address for wake enables. If zero unsupported.
532 * @irq_reg_stride: Stride to use for chips where registers are not contiguous.
533 * @init_ack_masked: Ack all masked interrupts once during initalization.
534 * @mask_invert: Inverted mask register: cleared bits are masked out.
535 * @use_ack: Use @ack register even if it is zero.
536 * @wake_invert: Inverted wake register: cleared bits are wake enabled.
537 * @runtime_pm: Hold a runtime PM lock on the device when accessing it.
538 *
539 * @num_regs: Number of registers in each control bank.
540 * @irqs: Descriptors for individual IRQs. Interrupt numbers are
541 * assigned based on the index in the array of the interrupt.
542 * @num_irqs: Number of descriptors.
543 */
562 };
574 #else
576 /*
577 * These stubs should only ever be called by generic code which has
578 * regmap based facilities, if they ever get called at runtime
579 * something is going wrong and something probably needs to select
580 * REGMAP.
581 */
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746 #endif
748 #endif