mirror of https://github.com/ArduPilot/ardupilot
457 lines
14 KiB
C++
457 lines
14 KiB
C++
// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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//
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// This is free software; you can redistribute it and/or modify it under
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// the terms of the GNU Lesser General Public License as published by the
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// Free Software Foundation; either version 2.1 of the License, or (at
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// your option) any later version.
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//
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/// @file AP_Param.h
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/// @brief A system for managing and storing variables that are of
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/// general interest to the system.
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#ifndef AP_PARAM_H
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#define AP_PARAM_H
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#include <stddef.h>
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#include <string.h>
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#include <stdint.h>
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#include <avr/pgmspace.h>
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#include <avr/eeprom.h>
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#define AP_MAX_NAME_SIZE 15
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// a varient of offsetof() to work around C++ restrictions.
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// this can only be used when the offset of a variable in a object
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// is constant and known at compile time
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#define AP_VAROFFSET(type, element) (((uintptr_t)(&((const type *)1)->element))-1)
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// find the type of a variable given the class and element
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#define AP_CLASSTYPE(class, element) (((const class *)1)->element.vtype)
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// declare a group var_info line
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#define AP_GROUPINFO(name, idx, class, element) { AP_CLASSTYPE(class, element), idx, name, AP_VAROFFSET(class, element) }
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// declare a nested group entry in a group var_info
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#define AP_NESTEDGROUPINFO(class, idx) { AP_PARAM_GROUP, idx, "", 0, class::var_info }
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#define AP_GROUPEND { AP_PARAM_NONE, 0xFF, "" }
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enum ap_var_type {
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AP_PARAM_NONE = 0,
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AP_PARAM_INT8,
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AP_PARAM_INT16,
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AP_PARAM_INT32,
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AP_PARAM_FLOAT,
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AP_PARAM_VECTOR3F,
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AP_PARAM_VECTOR6F,
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AP_PARAM_MATRIX3F,
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AP_PARAM_GROUP
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};
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/// Base class for variables.
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///
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/// Provides naming and lookup services for variables.
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///
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class AP_Param
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{
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public:
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// the Info and GroupInfo structures are passed by the main
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// program in setup() to give information on how variables are
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// named and their location in memory
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struct GroupInfo {
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uint8_t type; // AP_PARAM_*
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uint8_t idx; // identifier within the group
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const char name[AP_MAX_NAME_SIZE];
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uintptr_t offset; // offset within the object
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const struct GroupInfo *group_info;
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};
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struct Info {
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uint8_t type; // AP_PARAM_*
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const char name[AP_MAX_NAME_SIZE];
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uint8_t key; // k_param_*
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void *ptr; // pointer to the variable in memory
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const struct GroupInfo *group_info;
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};
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// a token used for first()/next() state
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typedef struct {
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uint8_t key;
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uint8_t group_element;
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uint8_t idx; // offset into array types
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} ParamToken;
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// called once at startup to setup the _var_info[] table. This
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// will also check the EEPROM header and re-initialise it if the
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// wrong version is found
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static bool setup(const struct Info *info, uint8_t num_vars, uint16_t eeprom_size);
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// return true if AP_Param has been initialised via setup()
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static bool initialised(void);
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/// Copy the variable's name, prefixed by any containing group name, to a buffer.
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///
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/// If the variable has no name, the buffer will contain an empty string.
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///
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/// Note that if the combination of names is larger than the buffer, the
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/// result in the buffer will be truncated.
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///
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/// @param buffer The destination buffer
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/// @param bufferSize Total size of the destination buffer.
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///
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void copy_name(char *buffer, size_t bufferSize, bool force_scalar=false);
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/// Find a variable by name.
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///
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/// If the variable has no name, it cannot be found by this interface.
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///
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/// @param name The full name of the variable to be found.
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/// @return A pointer to the variable, or NULL if
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/// it does not exist.
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///
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static AP_Param *find(const char *name, enum ap_var_type *ptype);
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/// Save the current value of the variable to EEPROM.
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///
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/// @return True if the variable was saved successfully.
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///
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bool save(void);
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/// Load the variable from EEPROM.
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///
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/// @return True if the variable was loaded successfully.
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///
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bool load(void);
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/// Load all variables from EEPROM
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///
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/// This function performs a best-efforts attempt to load all
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/// of the variables from EEPROM. If some fail to load, their
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/// values will remain as they are.
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///
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/// @return False if any variable failed to load
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///
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static bool load_all(void);
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/// Erase all variables in EEPROM.
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///
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static void erase_all(void);
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/// print the value of all variables
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static void show_all(void);
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/// Returns the first variable
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///
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/// @return The first variable in _var_info, or NULL if
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/// there are none.
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///
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static AP_Param *first(ParamToken *token, enum ap_var_type *ptype);
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/// Returns the next variable in _var_info, recursing into groups
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/// as needed
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static AP_Param *next(ParamToken *token, enum ap_var_type *ptype);
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/// Returns the next scalar variable in _var_info, recursing into groups
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/// as needed
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static AP_Param *next_scalar(ParamToken *token, enum ap_var_type *ptype);
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/// cast a variable to a float given its type
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float cast_to_float(enum ap_var_type type);
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private:
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/// EEPROM header
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///
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/// This structure is placed at the head of the EEPROM to indicate
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/// that the ROM is formatted for AP_Param.
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///
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struct EEPROM_header {
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uint8_t magic[2];
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uint8_t revision;
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uint8_t spare;
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};
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// This header is prepended to a variable stored in EEPROM.
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struct Param_header {
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uint8_t key;
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uint8_t group_element;
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uint8_t type;
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};
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// number of bits in each level of nesting of groups
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static const uint8_t _group_level_shift = 4;
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static const uint8_t _group_bits = 8;
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static const uint8_t _sentinal_key = 0xFF;
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static const uint8_t _sentinal_type = 0xFF;
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static const uint8_t _sentinal_group = 0xFF;
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static bool check_group_info(const struct GroupInfo *group_info, uint16_t *total_size, uint8_t max_bits);
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static bool check_var_info(void);
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const struct Info *find_var_info_group(const struct GroupInfo *group_info,
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uint8_t vindex,
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uint8_t group_base,
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uint8_t group_shift,
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uint8_t *group_element,
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const struct GroupInfo **group_ret,
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uint8_t *idx);
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const struct Info *find_var_info(uint8_t *group_element,
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const struct GroupInfo **group_ret,
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uint8_t *idx);
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static const struct Info *find_by_header_group(struct Param_header phdr, void **ptr,
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uint8_t vindex,
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const struct GroupInfo *group_info,
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uint8_t group_base,
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uint8_t group_shift);
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static const struct Info *find_by_header(struct Param_header phdr, void **ptr);
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void add_vector3f_suffix(char *buffer, size_t buffer_size, uint8_t idx);
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static AP_Param *find_group(const char *name, uint8_t vindex, const struct GroupInfo *group_info, enum ap_var_type *ptype);
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static void write_sentinal(uint16_t ofs);
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bool scan(const struct Param_header *phdr, uint16_t *pofs);
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static const uint8_t type_size(enum ap_var_type type);
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static void eeprom_write_check(const void *ptr, uint16_t ofs, uint8_t size);
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static AP_Param *next_group(uint8_t vindex, const struct GroupInfo *group_info,
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bool *found_current,
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uint8_t group_base,
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uint8_t group_shift,
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ParamToken *token,
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enum ap_var_type *ptype);
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static uint16_t _eeprom_size;
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static uint8_t _num_vars;
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static const struct Info *_var_info;
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// values filled into the EEPROM header
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static const uint8_t k_EEPROM_magic0 = 0x50;
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static const uint8_t k_EEPROM_magic1 = 0x41; ///< "AP"
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static const uint8_t k_EEPROM_revision = 5; ///< current format revision
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};
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/// Template class for scalar variables.
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///
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/// Objects of this type have a value, and can be treated in many ways as though they
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/// were the value.
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///
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/// @tparam T The scalar type of the variable
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/// @tparam PT The AP_PARAM_* type
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///
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template<typename T, ap_var_type PT>
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class AP_ParamT : public AP_Param
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{
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public:
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/// Constructor for scalar variable.
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///
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/// Initialises a stand-alone variable with optional initial value.
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///
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/// @param default_value Value the variable should have at startup.
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///
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AP_ParamT<T,PT> (const T initial_value = 0) :
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AP_Param(),
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_value(initial_value)
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{
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}
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static const ap_var_type vtype = PT;
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/// Value getter
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///
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T get(void) const {
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return _value;
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}
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/// Value setter
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///
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void set(T v) {
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_value = v;
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}
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/// Combined set and save
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///
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bool set_and_save(T v) {
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set(v);
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return save();
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}
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/// Combined set and save, but only does the save if the value if
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/// different from the current ram value, thus saving us a
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/// scan(). This should only be used where we have not set() the
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/// value separately, as otherwise the value in EEPROM won't be
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/// updated correctly.
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bool set_and_save_ifchanged(T v) {
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if (v == _value) {
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return true;
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}
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set(v);
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return save();
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}
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/// Conversion to T returns a reference to the value.
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///
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/// This allows the class to be used in many situations where the value would be legal.
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///
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operator T &() {
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return _value;
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}
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/// Copy assignment from self does nothing.
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///
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AP_ParamT<T,PT>& operator=(AP_ParamT<T,PT>& v) {
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return v;
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}
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/// Copy assignment from T is equivalent to ::set.
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///
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AP_ParamT<T,PT>& operator=(T v) {
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_value = v;
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return *this;
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}
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/// AP_ParamT types can implement AP_Param::cast_to_float
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///
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float cast_to_float(void) {
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return (float)_value;
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}
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protected:
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T _value;
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};
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/// Template class for non-scalar variables.
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///
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/// Objects of this type have a value, and can be treated in many ways as though they
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/// were the value.
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///
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/// @tparam T The scalar type of the variable
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/// @tparam PT AP_PARAM_* type
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///
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template<typename T, ap_var_type PT>
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class AP_ParamV : public AP_Param
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{
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public:
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static const ap_var_type vtype = PT;
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/// Value getter
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///
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T get(void) const {
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return _value;
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}
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/// Value setter
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///
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void set(T v) {
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_value = v;
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}
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/// Combined set and save
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///
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bool set_and_save(T v) {
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set(v);
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return save();
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}
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/// Conversion to T returns a reference to the value.
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///
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/// This allows the class to be used in many situations where the value would be legal.
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///
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operator T &() {
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return _value;
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}
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/// Copy assignment from self does nothing.
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///
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AP_ParamV<T,PT>& operator=(AP_ParamV<T,PT>& v) {
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return v;
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}
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/// Copy assignment from T is equivalent to ::set.
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///
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AP_ParamV<T,PT>& operator=(T v) {
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_value = v;
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return *this;
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}
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protected:
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T _value;
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};
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/// Template class for array variables.
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///
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/// Objects created using this template behave like arrays of the type T,
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/// but are stored like single variables.
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///
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/// @tparam T The scalar type of the variable
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/// @tparam N number of elements
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/// @tparam PT the AP_PARAM_* type
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///
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template<typename T, uint8_t N, ap_var_type PT>
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class AP_ParamA : public AP_Param
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{
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public:
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static const ap_var_type vtype = PT;
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/// Array operator accesses members.
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///
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/// @note It would be nice to range-check i here, but then what would we return?
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///
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T &operator [](uint8_t i) {
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return _value[i];
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}
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/// Value getter
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///
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/// @note Returns zero for index values out of range.
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///
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T get(uint8_t i) const {
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if (i < N) {
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return _value[i];
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} else {
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return (T)0;
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}
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}
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/// Value setter
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///
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/// @note Attempts to set an index out of range are discarded.
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///
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void set(uint8_t i, T v) {
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if (i < N) {
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_value[i] = v;
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}
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}
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/// Copy assignment from self does nothing.
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///
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AP_ParamA<T,N,PT>& operator=(AP_ParamA<T,N,PT>& v) {
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return v;
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}
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protected:
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T _value[N];
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};
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/// Convenience macro for defining instances of the AP_ParamT template.
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///
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#define AP_PARAMDEF(_t, _n, _pt) typedef AP_ParamT<_t, _pt> AP_##_n;
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AP_PARAMDEF(float, Float, AP_PARAM_FLOAT); // defines AP_Float
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AP_PARAMDEF(int8_t, Int8, AP_PARAM_INT8); // defines AP_Int8
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AP_PARAMDEF(int16_t, Int16, AP_PARAM_INT16); // defines AP_Int16
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AP_PARAMDEF(int32_t, Int32, AP_PARAM_INT32); // defines AP_Int32
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#define AP_PARAMDEFA(_t, _n, _size, _pt) typedef AP_ParamA<_t, _size, _pt> AP_##_n;
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AP_PARAMDEFA(float, Vector6f, 6, AP_PARAM_VECTOR6F);
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// this is used in AP_Math.h
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#define AP_PARAMDEFV(_t, _n, _pt) typedef AP_ParamV<_t, _pt> AP_##_n;
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/// Rely on built in casting for other variable types
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/// to minimize template creation and save memory
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#define AP_Uint8 AP_Int8
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#define AP_Uint16 AP_Int16
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#define AP_Uint32 AP_Int32
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#define AP_Bool AP_Int8
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#endif // AP_PARAM_H
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