//////////////////////////////////////////////////////////////////////
// LibFile: common.scad
//   Common functions used in argument processing.
//   To use, include this line at the top of your file:
//   ```
//   use <BOSL2/std.scad>
//   ```
//////////////////////////////////////////////////////////////////////


// Section: Type handling helpers.


// Function: typeof()
// Usage:
//   typ = typeof(x);
// Description:
//   Returns a string representing the type of the value.  One of "undef", "boolean", "number", "string", "list", or "range"
function typeof(x) =
	is_undef(x)? "undef" :
	is_bool(x)? "boolean" :
	is_num(x)? "number" :
	is_string(x)? "string" :
	is_list(x)? "list" :
	"range";


// Function: is_type()
// Usage:
//   b = is_type(x, types);
// Description:
//   Returns true if the type of the value `x` is one of those given as strings in the list `types`. 
//   Valid types are "undef", "boolean", "number", "string", "list", or "range"
// Arguments:
//   x = The value to check the type of.
//   types = A list of types to check 
// Example:
//   is_str_or_list = is_type("foo", ["string","list"]);   // Returns: true
//   is_str_or_list2 = is_type([1,2,3], ["string","list"]);  // Returns: true
//   is_str_or_list3 = is_type(2, ["string","list"]);  // Returns: false
//   is_str = is_type("foo", "string");  // Returns: true
//   is_str2 = is_type([3,4], "string");  // Returns: false
//   is_str3 = is_type(["foo"], "string");  // Returns: false
//   is_str4 = is_type(3, "string");  // Returns: false
function is_type(x,types) =
	is_list(types)? in_list(typeof(x),types) :
	is_string(types)? typeof(x) == types :
	assert(is_list(types)||is_string(types));


// Function: is_def()
// Usage:
//   is_def(x)
// Description:
//   Returns true if `x` is not `undef`.  False if `x==undef`.
function is_def(x) = !is_undef(x);


// Function: is_str()
// Usage:
//   is_str(x)
// Description:
//   Returns true if `x` is a string.  A shortcut for `is_string()`.
function is_str(x) = is_string(x);


// Function: is_int()
// Usage:
//   is_int(n)
// Description:
//   Returns true if the given value is an integer (it is a number and it rounds to itself).  
function is_int(n) = is_num(n) && n == round(n);
function is_integer(n) = is_num(n) && n == round(n);


// Function: is_nan()
// Usage:
//   is_nan(x);
// Description:
//   Returns true if a given value `x` is nan, a floating point value representing "not a number".
function is_nan(x) = (x!=x);


// Function: is_range()
// Description:
//   Returns true if its argument is a range
function is_range(x) = is_num(x[0]) && !is_list(x);

// Function: is_list_of()
// Usage:
//   is_list_of(list, pattern)
// Description:
//   Tests whether the input is a list whose entries are all numeric lists that have the same
//   list shape as the pattern.
// Example:
//   is_list_of([3,4,5], 0);            // Returns true
//   is_list_of([3,4,undef], 0);        // Returns false
//   is_list_of([[3,4],[4,5]], [1,1]);  // Returns true
//   is_list_of([[3,4], 6, [4,5]], [1,1]);  // Returns false
//   is_list_of([[1,[3,4]], [4,[5,6]]], [1,[2,3]]);    // Returne true
//   is_list_of([[1,[3,INF]], [4,[5,6]]], [1,[2,3]]);  // Returne false
function is_list_of(list,pattern) =
	let(pattern = 0*pattern)
	is_list(list) &&
	[]==[for(entry=list) if (entry*0 != pattern) entry];


// Function: is_consistent()
// Usage:
//   is_consistent(list)
// Description:
//   Tests whether input is a list of entries which all have the same list structure
//   and are filled with finite numerical data.
// Example:
//   is_consistent([3,4,5]);              // Returns true
//   is_consistent([[3,4],[4,5],[6,7]]);  // Returns true
//   is_consistent([[3,4,5],[3,4]]);      // Returns false
//   is_consistent([[3,[3,4,[5]]], [5,[2,9,[9]]]]); // Returns true
//   is_consistent([[3,[3,4,[5]]], [5,[2,9,9]]]);   // Returns false
function is_consistent(list) =
  is_list(list) && is_list_of(list, list[0]);


// Function: same_shape()
// Usage:
//   same_shape(a,b)
// Description:
//   Tests whether the inputs `a` and `b` are both numeric and are the same shaped list.
// Example:
//   same_shape([3,[4,5]],[7,[3,4]]);   // Returns true
//   same_shape([3,4,5], [7,[3,4]]);    // Returns false
function same_shape(a,b) = a*0 == b*0;


// Section: Handling `undef`s.


// Function: default()
// Description:
//   Returns the value given as `v` if it is not `undef`.
//   Otherwise, returns the value of `dflt`.
// Arguments:
//   v = Value to pass through if not `undef`.
//   dflt = Value to return if `v` *is* `undef`.
function default(v,dflt=undef) = is_undef(v)? dflt : v;


// Function: first_defined()
// Description:
//   Returns the first item in the list that is not `undef`.
//   If all items are `undef`, or list is empty, returns `undef`.
// Arguments:
//   v = The list whose items are being checked.
//   recursive = If true, sublists are checked recursively for defined values.  The first sublist that has a defined item is returned.
function first_defined(v,recursive=false,_i=0) =
	_i<len(v) && (
		is_undef(v[_i]) || (
			recursive &&
			is_list(v[_i]) &&
			is_undef(first_defined(v[_i],recursive=recursive))
		)
	)? first_defined(v,recursive=recursive,_i=_i+1) : v[_i];


// Function: one_defined()
// Usage:
//   one_defined(vars, names, [required])
// Description:
//   Examines the input list `vars` and returns the entry which is not `undef`.  If more
//   than one entry is `undef` then issues an assertion specifying "Must define exactly one of" followed
//   by the defined items from the `names` parameter.  If `required` is set to false then it is OK if all of the
//   entries of `vars` are undefined, and in this case, `undef` is returned.
// Example:
//   length = one_defined([length,L,l], ["length","L","l"]);
function one_defined(vars, names, required=true) =
   assert(len(vars)==len(names))
   let (
     ok = num_defined(vars)==1 || (!required && num_defined(vars)==0)
   )
   assert(ok,str("Must define ",required?"exactly":"at most"," one of ",[for(i=[0:len(vars)]) if (is_def(vars[i])) names[i]]))
   first_defined(vars);


// Function: num_defined()
// Description: Counts how many items in list `v` are not `undef`.
function num_defined(v,_i=0,_cnt=0) = _i>=len(v)? _cnt : num_defined(v,_i+1,_cnt+(is_undef(v[_i])? 0 : 1));


// Function: any_defined()
// Description:
//   Returns true if any item in the given array is not `undef`.
// Arguments:
//   v = The list whose items are being checked.
//   recursive = If true, any sublists are evaluated recursively.
function any_defined(v,recursive=false) = first_defined(v,recursive=recursive) != undef;


// Function: all_defined()
// Description:
//   Returns true if all items in the given array are not `undef`.
// Arguments:
//   v = The list whose items are being checked.
//   recursive = If true, any sublists are evaluated recursively.
function all_defined(v,recursive=false) = max([for (x=v) is_undef(x)||(recursive&&is_list(x)&&!all_defined(x))? 1 : 0])==0;




// Section: Argument Helpers


// Function: get_anchor()
// Usage:
//   get_anchor(anchor,center,[uncentered],[dflt]);
// Description:
//   Calculated the correct anchor from `anchor` and `center`.  In order:
//   - If `center` is not `undef` and `center` evaluates as true, then `CENTER` (`[0,0,0]`) is returned.
//   - Otherwise, if `center` is not `undef` and `center` evaluates as false, then the value of `uncentered` is returned.
//   - Otherwise, if `anchor` is not `undef`, then the value of `anchor` is returned.
//   - Otherwise, the value of `dflt` is returned.
//   This ordering ensures that `center` will override `anchor`.
// Arguments:
//   anchor = The anchor name or vector.
//   center = If not `undef`, this overrides the value of `anchor`.
//   uncentered = The value to return if `center` is not `undef` and evaluates as false.  Default: ALLNEG
//   dflt = The default value to return if both `anchor` and `center` are `undef`.  Default: `CENTER`
function get_anchor(anchor,center,uncentered=BOT,dflt=CENTER) =
	!is_undef(center)? (center? CENTER : uncentered) :
	!is_undef(anchor)? anchor :
	dflt;


// Function: get_radius()
// Usage:
//   get_radius([r1], [r2], [r], [d1], [d2], [d], [dflt]);
// Description:
//   Given various radii and diameters, returns the most specific radius.
//   If a diameter is most specific, returns half its value, giving the radius.
//   If no radii or diameters are defined, returns the value of dflt.
//   Value specificity order is r1, r2, d1, d2, r, d, then dflt
//   Only one of `r1`, `r2`, `d1`, or `d2` can be defined at once, or else it
//   errors out, complaining about conflicting radius/diameter values.
//   Only one of `r` or `d` can be defined at once, or else it errors out,
//   complaining about conflicting radius/diameter values.
// Arguments:
//   r1 = Most specific radius.
//   d1 = Most specific diameter.
//   r2 = Second most specific radius.
//   d2 = Second most specific diameter.
//   r = Most general radius.
//   d = Most general diameter.
//   dflt = Value to return if all other values given are `undef`.
function get_radius(r1=undef, r2=undef, r=undef, d1=undef, d2=undef, d=undef, dflt=undef) = (
	!is_undef(r1)? assert(is_undef(r2)&&is_undef(d1)&&is_undef(d2), "Conflicting or redundant radius/diameter arguments given.") r1 :
	!is_undef(r2)? assert(is_undef(d1)&&is_undef(d2), "Conflicting or redundant radius/diameter arguments given.") r2 :
	!is_undef(d1)? d1/2 :
	!is_undef(d2)? d2/2 :
	!is_undef(r)? assert(is_undef(d), "Conflicting or redundant radius/diameter arguments given.") r :
	!is_undef(d)? d/2 :
	dflt
);

// Function: get_height()
// Usage:
//   get_height([h],[l],[height],[dflt])
// Description:
//   Given several different parameters for height check that height is not multiply defined
//   and return a single value.  If the three values `l`, `h`, and `height` are all undefined
//   then return the value `dflt`, if given, or undef otherwise.
// Arguments:
//   l = l.
//   h = h.
//   height = height.
//   dflt = Value to return if other values are `undef`. 
function get_height(h=undef,l=undef,height=undef,dflt=undef) =
    assert(num_defined([h,l,height])<=1,"You must specify only one of `l`, `h`, and `height`")
    first_defined([h,l,height,dflt]);


// Function: scalar_vec3()
// Usage:
//   scalar_vec3(v, [dflt]);
// Description:
//   If `v` is a scalar, and `dflt==undef`, returns `[v, v, v]`.
//   If `v` is a scalar, and `dflt!=undef`, returns `[v, dflt, dflt]`.
//   If `v` is a vector, returns the first 3 items, with any missing values replaced by `dflt`.
//   If `v` is `undef`, returns `undef`.
// Arguments:
//   v = Value to return vector from.
//   dflt = Default value to set empty vector parts from.
function scalar_vec3(v, dflt=undef) =
	is_undef(v)? undef :
	is_list(v)? [for (i=[0:2]) default(v[i], default(dflt, 0))] :
	!is_undef(dflt)? [v,dflt,dflt] : [v,v,v];


// Function: segs()
// Usage:
//   sides = segs(r);
// Description:
//   Calculate the standard number of sides OpenSCAD would give a circle based on `$fn`, `$fa`, and `$fs`.
// Arguments:
//   r = Radius of circle to get the number of segments for.
function segs(r) =
	$fn>0? ($fn>3? $fn : 3) :
	ceil(max(5, min(360/$fa, abs(r)*2*PI/$fs)));


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