Place holder
library to help with both parsing and validation of config files.
For some configuration files, validating the structure of the parsed settings (required keys are present, no unknown keys are present, values have acceptable types.) can be as time consuming as the parsing of the syntax.
- Based on libconfig
- C++17 based.
- will allow the user to specify a schema for the target configuration.
- will be setup to work nicely with FetchConfig.
- throw as little as possible without making the interface horrible.
- Only one integer type (long)
- Only one float type (double)
- Hex numbers are integers only
//sample schema file
// valid types are "string", "int", "float" , "group", "list", "array"
// note : 1000 will parse as either a float or an int, but 1000.0 will only parse as a float.
default-osc = { type : "string", required : "no" }
midi { type : "group", required : "yes"
// key* means it has any number of keys with given form
key* = { type : "group",
// keys are the exact keys that must be in the group.
// both keys and key* are usable inside the same group.
keys = {
in : { type : "String", required : "yes" }
osc : { type : "string", required : "no" }
}
}
}
// sample usage
#include <configinator5000.hpp>
#include <string>
std::string schema = R"DELIM(
// long schema ....
)DELIM"s
Configinator5000::Configinator cfg;
if (!cfg.set_schema(schema)) {
std::cerr << "Bad Schema\n";
}
if (! cfg.parse(file_name)) {
std::cerr << "Yikes\n";
}
// Or
if (! cfg.parse(my_istream)) {
std::cerr << "Yikes again!\n";
}bool parse_file(std::string file_name)bool parse(std::ifstream& strm)bool parse(std::string& input)
Prse the given information and store a setting tree for it. The return tells
you if it succeeded or not. If the return value is false, the errors are most
likely available with stream_errors.
Setting& get_settngs()
Return a reference to the setting tree. If the last parse failed, this will be partial, but valid until the point of failure.
std::ostream& stream_errors(std::ostream& strm)
Format the error message gathered during parsing and place on the output stream.
The heart of the system. A Setting represents a value (not a key/value) - it can be either a scalar (long, bool, double, string) or composite (group, list, array).
Setting(setting_type t = setting_type::BOOL)
Create a Setting of the desired type of value. The actual value is the default initialized value for the type.
Setting(bool b)Setting(int i)Setting(long i)Setting(double f)Setting(std::string s)Setting(const char * c)
Create a Setting with the desired value and type. Some apparent duplicates are there to help disabiguate the overloads.
-
bool is_composite() -
bool is_scalar() -
bool is_boolean() -
bool is_integer() -
bool is_float() -
bool is_string() -
bool is_group() -
bool is_list() -
bool is_array() -
bool is_numeric()
Setting & set_value(bool v)Setting & set_value(int v)Setting & set_value(long v)Setting & set_value(double v)Setting & set_value(const std::string v)Setting & set_value(const char * v)
Update the Setting to have the value and type specified. These are mutators. The reference to the object is returned to facilitate chaining.
If the Setting is currently composite, these will remove any attached children and switch the type to the correct scalar type.
NOTE The reference may become invalid if more children are added to the composite. Don't hold on to it for long.
Setting& make_list()Setting& make_group()Setting& make_array()
Switches the Setting to be the requested type of composite. If it already is correct, this is a no-op. If the type actually changes, any existing children will be discarded.
int count()
Return how many children the composite has. Actually also works with scalars where it always returns 0.
Setting& add_child(setting_type t)
Add a child of type t. The value for scalars will be the default initialized
value. The throws an exception for groups since children for groups must have
names. Also throws for scalars.
NOTE The reference may become invalid if more children are added to the composite. Don't hold on to it for long.
template\<typename T\> Setting& add_child(T value)
Attempts to deduce the correct scalar type for T and create a child of that type initialized to the value. This throws an exception for groups since children for groups must have names. Also throws for scalars.
NOTE The reference may become invalid if more children are added to the composite. Don't hold on to it for long.
Setting& add_child(std::string name, setting_type t)Setting& add_child(std::string name, T value)
Variants of the above for groups. Throws for scalars or non-group composites.
NOTE The reference may become invalid if more children are added to the composite. Don't hold on to it for long.
Setting &at(int idx)
Return a reference to the child at index idx. Negative values count from the end. The method throws if the index is out of range or the Setting is a scalar.
Note that this does work for groups, but you don't get access to the name.
bool exists(std::string name)
Checks if a given key exists in a group. Returns true if:
- The Setting is a group
- The key exists. Returns true otherwise.
Returns a reference to the child added with name name. Throws if such a child
does not exist or the Setting is not a group.
iterator& begin()iterator& end()
Return the STL style iterators. These work for all composite types. However, for groups, it ONLY returns the values and it returns them in insert order rather than key order.
Range-for is supported:
Setting & setting{Setting::setting_type::LIST};
setting.add_child(1);
// ...
for (auto &c : setting) {
/* something */
}enumerator & enumerate()
This is for use with groups and will throw if not a group. This returns the
reference to an object which can iterate over the groups key/value pairs. To
get an actual iterator, use begin(). The easiest way to use this is with
range-for.
The iterator returns a std:pair where the first is the key and second is
the Setting & value.
This returns key/value pairs in key order regardless of insert order.
Setting & setting{Setting::setting_type::GROUP};
setting.add_child("b", 2);
setting.add_child("a", 12);
// ...
for (auto &c : setting.enumerate()) {
std::cout << c->first << " : " << c->second.get<int>() << "\n";
}
// more manually ...
auto & e = setting.enumerate();
for (auto &iter = e.begin(); iter != e.end(); ++iter) {
std::cout << c->first << " : " << c->second.get<int>() << "\n";
}