rockbox/utils/regtools/lib/soc_desc.hpp

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/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2012 by Amaury Pouly
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#ifndef __SOC_DESC__
#define __SOC_DESC__
#include <stdint.h>
#include <vector>
#include <list>
#include <string>
#include <map>
/**
* These data structures represent the SoC register in a convenient way.
* The basic structure is the following:
* - each SoC has several devices
* - each device has a generic name, a list of {name,address} and several registers
* - each register has a generic name, a list of {name,address}, flags,
* several fields
* - each field has a name, a first and last bit position, can apply either
* to all addresses of a register or be specific to one only and has several values
* - each field value has a name and a value
*
* All addresses, values and names are relative to the parents. For example a field
* value BV_LCDIF_CTRL_WORD_LENGTH_18_BIT is represented has:
* - device LCDIF, register CTRL, field WORD_LENGTH, value 16_BIT
* The address of CTRL is related to the address of LCDIF, the value of 16_BIT
* ignores the position of the WORD_LENGTH field in the register.
*/
/**
* Typedef for SoC types: word, address and flags */
typedef uint32_t soc_addr_t;
typedef uint32_t soc_word_t;
typedef uint32_t soc_reg_flags_t;
/** SoC error gravity level */
enum soc_error_level_t
{
SOC_ERROR_WARNING,
SOC_ERROR_FATAL,
};
/** SoC description error */
struct soc_error_t
{
soc_error_level_t level; /// level (warning, fatal, ...)
std::string location; /// human description of the location
std::string message; /// message
};
/** SoC register generic formula */
enum soc_reg_formula_type_t
{
REG_FORMULA_NONE, /// register has no generic formula
REG_FORMULA_STRING, /// register has a generic formula represented by a string
};
/** <soc_reg_t>.<flags> values */
const soc_reg_flags_t REG_HAS_SCT = 1 << 0; /// register SCT variants
/** SoC register field named value */
struct soc_reg_field_value_t
{
std::string name; /// name of the value
soc_word_t value; /// numeric value
std::string desc; /// human description
std::vector< soc_error_t > errors(bool recursive);
};
/** SoC register field */
struct soc_reg_field_t
{
std::string name; /// name of the field
std::string desc; /// human description
unsigned first_bit, last_bit; /// bit range of the field
soc_word_t bitmask() const
{
// WARNING beware of the case where first_bit=0 and last_bit=31
if(first_bit == 0 && last_bit == 31)
return 0xffffffff;
else
return ((1 << (last_bit - first_bit + 1)) - 1) << first_bit;
}
bool is_reserved() const
{
return name.substr(0, 4) == "RSVD" || name.substr(0, 5) == "RSRVD";
}
std::vector< soc_reg_field_value_t > value;
std::vector< soc_error_t > errors(bool recursive);
};
/** SoC register address */
struct soc_reg_addr_t
{
std::string name; /// actual register name
soc_addr_t addr; /// actual register address (relative to device)
std::vector< soc_error_t > errors(bool recursive);
};
/** SoC register formula */
struct soc_reg_formula_t
{
enum soc_reg_formula_type_t type;
std::string string; /// for STRING
std::vector< soc_error_t > errors(bool recursive);
};
/** SoC register */
struct soc_reg_t
{
std::string name; /// generic name (for multi registers) or actual name
std::string desc; /// human description
std::vector< soc_reg_addr_t > addr; /// instances of the registers
soc_reg_formula_t formula; /// formula for the instance addresses
soc_reg_flags_t flags; /// ORed value
std::vector< soc_reg_field_t > field;
std::vector< soc_error_t > errors(bool recursive);
};
/** Soc device address */
struct soc_dev_addr_t
{
std::string name; /// actual device name
soc_addr_t addr;
std::vector< soc_error_t > errors(bool recursive);
};
/** SoC device */
struct soc_dev_t
{
std::string name; /// generic name (of multi devices) or actual name
std::string long_name; /// human friendly name
std::string desc; /// human description
std::string version; /// description version
std::vector< soc_dev_addr_t > addr;
std::vector< soc_reg_t > reg;
std::vector< soc_error_t > errors(bool recursive);
};
/** SoC */
struct soc_t
{
std::string name; /// codename (rockbox)
std::string desc; /// SoC name
std::vector< soc_dev_t > dev;
std::vector< soc_error_t > errors(bool recursive);
};
/** Parse a SoC description from a XML file, append it to <soc>. */
bool soc_desc_parse_xml(const std::string& filename, soc_t& soc);
/** Write a SoC description to a XML file, overwriting it. A file can contain
* multiple Soc descriptions */
bool soc_desc_produce_xml(const std::string& filename, const soc_t& soc);
/** Normalise a soc description by reordering elemnts so that:
* - devices are sorted by first name
* - registers are sorted by first address
* - fields are sorted by last bit
* - values are sorted by value */
void soc_desc_normalize(soc_t& soc);
/** Formula parser: try to parse and evaluate a formula to a specific value of 'n' */
bool soc_desc_evaluate_formula(const std::string& formula,
const std::map< std::string, soc_word_t>& var, soc_word_t& result, std::string& error);
#endif /* __SOC_DESC__ */