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utility

Index


AddNamedObject() AllocateTagItems() AllocNamedObjectA() Amiga2Date()
ApplyTagChanges() AttemptRemNamedObject() CallHookPkt() CheckDate()
ClearMem() CloneTagItems() Date2Amiga() FilterTagChanges()
FilterTagItems() FindNamedObject() FindTagItem() FreeNamedObject()
FreeTagItems() GetTagData() GetUniqueID() MapTags()
MoveMem() NamedObjectName() NextTagItem() PackBoolTags()
PackStructureTags() RefreshTagItemClones() ReleaseNamedObject() RemNamedObject()
SDivMod32() SetMem() SMult32() SMult64()
Stricmp() Strlcat() Strlcpy() Strnicmp()
TagInArray() ToLower() ToUpper() UDivMod32()
UMult32() UMult64() UnpackStructureTags() VSNPrintf()

AddNamedObject()

Synopsis

BOOL AddNamedObject(
         struct NamedObject * nameSpace,
         struct NamedObject * object );

Function

Adds a given NamedObject to a NameSpace which is addressed through
a second NamedObject. Allows you to link a common group of
NamedObjects together. If the NameSpace doesn't support duplicate
names, then a search for a duplicate will be made, and FALSE returned
if one is found.

Inputs

nameSpace   -   The NameSpace to add the NamedObject object to.
                If this value is NULL, then the NamedObject will
                be added to the root NameSpace. This is useful
                for sharing NamedObjects between Tasks.
object      -   The NamedObject to add to the NameSpace.

Result

If the NamedObject can be added to either the supplied NameSpace or
the system global NameSpace, this function will return TRUE.

Otherwise it will return FALSE. This will generally happen when
the NSF_NODUPS flag is set and this NamedObject has the same name
as a second object, or when the object is already in a NameSpace.

Notes

See BUGS.

Bugs

Although the AmigaOS 3.1 autodocs did not say so, under 3.0 you
couldn't add a NamedObject to a NameSpace when the NamedObject you
were adding had a NameSpace itself. This has changed. This is
because the autodocs did not say this, and they are right :)

AllocateTagItems()

Synopsis

struct TagItem * AllocateTagItems(
         ULONG numTags );

Function

Allocate a number of TagItems in an array for whatever you like.
The memory allocated will be cleared.

Inputs

numTags     - The number of TagItems to allocate.

Result

A pointer to an array of struct TagItem containing numTags tags.

Example

struct TagItem *tagList;

tagList =  AllocateTagItems( 4 );

tagList[0].ti_Tag  = NA_Name;
tagList[0].ti_Data = (IPTR)"A list of tags";
tagList[3].ti_Tag  = TAG_DONE;

\* Do what you want with your TagList here ... *\

FreeTagItems( tagList );

Notes

The number you supply must include the terminating tag (ie TAG_DONE)
There is no provision for extra TagItems at the end of the list.

If the number of tags to allocate is zero, then none will be.

AllocNamedObjectA()

Synopsis

struct NamedObject * AllocNamedObjectA(
         CONST_STRPTR name,
         CONST struct TagItem * tagList );

struct NamedObject * AllocNamedObject(
         CONST_STRPTR name,
         TAG tag, ... );

Function

Allocates a new NamedObject and initializes it as requested.
This object can then be used as an object in a name space.
Optionally you give this object a name space, and use it to
nest name spaces. You can also allocate some memory which is
attached to this object for your own personal use.

When the object is allocated, it will automatically have one user.
To allow other users to remove this object from a namespace, you
must call ReleaseNamedObject() on this object.

Inputs

name    -   The name of the NamedObject. Obviously this MUST be
            specified (otherwise it wouldn't be named would it?)
tagList -   A TagList containing some extra information for this
            NamedObject. These are:

            ANO_NameSpace: Allocate a NameSpace for this
                NamedObject. This will allow you to link other
                NamedObjects into a group. You cannot add a
                NamedObject with a NameSpace to another NameSpace.
                Boolean, default is FALSE.

            ANO_UserSpace: This tag says that you want extra memory
                allocated for a UserSpace. The ti_Data field of
                this TagItem contains the amount of memory to
                allocate. Specifying this Tag with a ti_Data of 0,
                is equivalent to the default, which is no UserSpace.
                The UserSpace address can be found in the no_Object
                field of the NamedObject structure.

            ANO_Priority: This is the List priority of the
                NamedObject and should be a signed BYTE value
                between -128 and 127. This is taken into account
                in adding and finding NamedObjects, as the highest
                priority NamedObject will be returned first. The
                default value is 0.

            ANO_Flags: This allows you to initialize the value of
                the NameSpace flags which control certain aspects
                of the NameSpace. See the file utility/name.h.

Result

A pointer to a new NamedObject, or NULL if the allocation failed
due to no free memory.

Amiga2Date()

Synopsis

void Amiga2Date(
         ULONG seconds,
         struct ClockData * result );

Function

Convert the time value given as the number of seconds since the
1st of January 1978 (00:00:00 1.1.78), to a more useful values,
which is easier for most people to understand. These values will
be stored in the ClockData structure whose address is passed as
an argument.

Inputs

seconds     -   Number of seconds since 1.1.78 00:00:00
result      -   The ClockData structure to store the information
                in.

Result

The ClockData structure will contain the converted time values.

ApplyTagChanges()

Synopsis

void ApplyTagChanges(
         struct TagItem * list,
         struct TagItem * changelist );

void ApplyTagChangesTags(
         struct TagItem * list,
         TAG tag, ... );

AttemptRemNamedObject()

Synopsis

LONG AttemptRemNamedObject(
         struct NamedObject * object );

Function

Checks to see whether a NamedObject can be removed. If the object
is in use, or in the process of being removed, this function will
return a failure code. If the object can be removed, this function
will remove it and the object will be available for freeing.
You must have previously have called FindNamedObject() on this
object.

Inputs

object      - NamedObject to attempt to remove. The address of the
                NameSpace is contained within the NamedObject.

Result

If the NamedObject can be removed, then it will be removed from
the list. Otherwise the routine will just return.

If the NamedObject has a removal message associated with it that
message will be returned to the owner of the NamedObject.

CallHookPkt()

Synopsis

IPTR CallHookPkt(
         struct Hook * hook,
         APTR object,
         APTR paramPacket );

Function

Call the callback hook defined by a Hook structure.
This is effectively a long jump to the hook->h_Entry vector
of the structure.

The Hook will be called with the same arguments as this function.
If your compiler cannot support correctly registered arguments
(most can), you can use the HookEntry function defined in amiga.lib
to push the arguments on the stack and call your function.

See the include file utility/hooks.h for more information.

Inputs

hook        -   Pointer to an initialized Hook structure. See the
                include file <utility/hooks.h> for a definition.
object      -   The object that this Hook is to act upon.
paramPacket -   The arguments to this callback. This will depend
                entirely on the type of the object.

Result

Depends upon the Hook itself.

Bugs

If your callback function does not have the correct register
definitions, the result of this function is entirely unreliable.

You can get the correct register definitions by using the AROS_UFHA()
macros (See <utility/hooks.h>).

See also

amiga.lib/CallHook()


CheckDate()

Synopsis

ULONG CheckDate(
         struct ClockData * date );

Function

Examine the date described in the ClockData structure and
determine whether it is a valid date. In particular this
checks whether the ranges of the fields are within normal
limits.

This function does not check whether the wday field of the
ClockData structure is valid.

Inputs

date        -   A ClockData structure desribing the date
                to check.

Result

If the date is valid, the number of seconds from midnight
1-Jan-1978 AD to the date, or 0 if the date is invalud.

Notes

The date 01-Jan-78 00:00:00 is actually returned as invalid.

This also assumes that the ClockDate refers to a date in the
Gregorian calendar. (60 sec/min, 60 min/hour, 24 hr/day,
12 months/year).

Bugs

Does not check whether the 29/2 is valid outside of a leap year.

ClearMem()

Synopsis

VOID ClearMem(
         APTR destination,
         ULONG size );

CloneTagItems()

Synopsis

struct TagItem * CloneTagItems(
         const struct TagItem * tagList );

struct TagItem * CloneTagItemsTags(
         TAG tag, ... );

Function

Duplicates a TagList. The input TagList can be NULL, in which
case an empty TagList will be returned.

Inputs

tagList     -   The TagList that you want to clone

Result

A TagList which contains a copy of the TagItems contained in the
original list. The list is cloned so that calling FindTagItem()
on a tag in the clone will return the same value as that in the
original list (assuming the original has not been modified).

Example

struct TagItem *tagList, *tagListClone;

\* Set up the original taglist tagList *\

tagListClone = CloneTagItems( tagList );

\* Do what you want with your TagList here *\

FreeTagItems( tagListClone );

Date2Amiga()

Synopsis

ULONG Date2Amiga(
         struct ClockData * date );

Function

Converts the information given in the struct ClockData *date, into
the number of seconds that have past since the 1st of January 1978.

Inputs

date    -   Contains the information about the time.

Result

The number of seconds since 1.1.1978

FilterTagChanges()

Synopsis

void FilterTagChanges(
         struct TagItem * changeList,
         const struct TagItem * originalList,
         BOOL apply );

Function

This function will scan through changeList, and if an item in
changeList exists in originalList, but both items data values
are equal, then the item in changeList will be removed from the
list.

If the value of apply is TRUE, then if the datas are different
then the values in originalList will be updated to match those
in changeList.

Inputs

changeList      -   List of new tags (may be NULL).
originalList    -   List of existing tags (may be NULL).
apply           -   Boolean flag as to whether the values in
                    originalList should be updated to match
                    those in changeList.

Result

The changeList will be modified to show altered items, and if
requested, the originalList will be updated.

FilterTagItems()

Synopsis

ULONG FilterTagItems(
         struct TagItem * tagList,
         Tag            * filterArray,
         ULONG logic );

Function

Scans a tag list and removes tag items from the list depending
upon whether the tag's Tag value is found in an array of tag
values.

If 'logic' is TAGFILTER_AND, then all the tags that are NOT
in the array filterArray will be removed from the tagList.

If 'logic' is TAGFILTER_NOT, then all the tags that ARE in
the array filterArray will be removed from the tagList.

Tags are removed by setting their ti_Tag value to TAG_IGNORE.

Inputs

tagList         -   A TagList to filter items from.
filterArray     -   An array (as described by TagInArray())
                    to determine which tag items are to be
                    removed.
logic           -   Whether the tags in filterArray are to be
                    included or excluded from the tag list.

Result

The number of valid items left in the resulting filtered list.

FindNamedObject()

Synopsis

struct NamedObject * FindNamedObject(
         struct NamedObject * nameSpace,
         CONST_STRPTR name,
         struct NamedObject * lastObject );

Function

This function will search through a given NameSpace, or the
system global NameSpace to find a NamedObject with the name
requested. Optionally you can have the search start from a
specific NamedObject. This way you can look for each occurence
of a specifically named NamedObject in a NameSpace that allows
for duplicates.

Inputs

nameSpace   -   The NameSpace to search through. If NULL will use
                the system default NameSpace.
name        -   The name of the object to search for. If NULL,
                any and all NamedObjects will be matched.
lastObject  -   The (optional) last NamedObject to start the search
                from.

Result

If a NamedObject with the name supplied exists, it will be returned.
Otherwise will return NULL.

When you have finised with this NamedObject, you should call
ReleaseNamedObject( NamedObject ).

Notes

If you are going to use a returned NamedObject to be the starting
point for another search you must call ReleaseNamedObject() AFTER
searching, as the ReleaseNamedObject() call can cause the NamedObject
to be freed, leaving you with an invalid pointer.

FindTagItem()

Synopsis

struct TagItem * FindTagItem(
         Tag tagValue,
         const struct TagItem * tagList );

struct TagItem * FindTagItemTags(
         Tag tagValue,
         TAG tag, ... );

FreeNamedObject()

Synopsis

void FreeNamedObject(
         struct NamedObject * object );

Function

Frees a NamedObject previously allocated by AllocNamedObject().

Inputs

object      -   The NamedObject that you wish to free.

Result

The memory used by the NamedObject will be returned to the
systems free memory pool.

FreeTagItems()

Synopsis

void FreeTagItems(
         struct TagItem * tagList );

void FreeTagItemsTags(
         TAG tag, ... );

Function

Free a list of TagItems which was allocated by AllocateTagItems().

Inputs

tagList     - A list of TagItems - must have been allocated by
              AllocateTagItems() or CloneTagItems().

Result

The memory containing the tagList is returned to the system.

Example

struct TagItem *tagList;

tagList =  AllocateTagItems( 4 );

tagList[0].ti_Tag  = NA_Name;
tagList[0].ti_Data = (IPTR)"A list of tags";
tagList[3].ti_Tag  = TAG_DONE;

\* Do what you want with your TagList here ... *\

FreeTagItems( tagList );

Notes

The memory will only be freed if the input is non-NULL.

GetTagData()

Synopsis

IPTR GetTagData(
         Tag tagValue,
         IPTR defaultVal,
         const struct TagItem * tagList );

IPTR GetTagDataTags(
         Tag tagValue,
         IPTR defaultVal,
         TAG tag, ... );

Function

Searches the TagList for the Tag specified, if it exists, then
returns the ti_Data field of that Tag, otherwise returns the
supplied default value.

Inputs

tagValue    -   Tag to search for.
defaultVal  -   Default value for the Tag.
tagList     -   Pointer to first TagItem in the list.

Result

The data value if the Tag exists, or the default value if it
doesn't.

Example

struct Window *window;      \* The Window we are creating *\
struct TagItem *wintags;    \* Tags for this window *\

\* Find out the value for the WA_Left tag *\
window->Left = GetTagData( WA_Left, 320, wintags )

Notes

If the input TagList doesn't exist (eg for some reason equals
NULL), then the return value will be NULL. This way you can
check for broken code, whereas returing the default would allow
code that is possibly buggy to still seem to work. (Until you
tried to do anything special at least).

GetUniqueID()

Synopsis

ULONG GetUniqueID();

Function

Returns a unique id that is different from any other id that is
obtained from this function call.

Result

an unsigned long id

MapTags()

Synopsis

void MapTags(
         struct TagItem * tagList,
         struct TagItem * mapList,
         ULONG mapType );

Function

Replace the ti_Tags in tagList which match the ti_Tags in mapList
by the ti_Data values of mapList.

Inputs

tagList - This list is modified
mapList - This defines which ti_Tag is replaced with what new value.

Result

None.

MoveMem()

Synopsis

VOID MoveMem(
         APTR source,
         APTR destination,
         ULONG size );

NamedObjectName()

Synopsis

STRPTR NamedObjectName(
         struct NamedObject * object );

Function

Return the name associated with a NamedObject.

Inputs

object      -   The NamedObject you want the name of.

Result

The name of the object will be returned.

Example

struct NamedObject *no;
STRPTR name;

\* Some other code here *\

name = NamedObjectName( no );

NextTagItem()

Synopsis

struct TagItem * NextTagItem(
         struct TagItem ** tagListPtr );

Function

Returns the address of the next tag-item in the list. This
routine correctly handles TAG_END, TAG_DONE, TAG_MORE,
TAG_IGNORE and TAG_SKIP.

TAG_END and TAG_DONE both terminate a TagItems-array (in
fact, TAG_DONE is the same as TAG_END).

With TAG_MORE, you can redirect the processing to a new list
of tags. Note that the processing will not return to the previous
list when a TAG_END/TAG_DONE is encountered.

TAG_IGNORE disables the processing of an entry in the list.
This entry is just ignored (We use this technique for filtering).

TAG_SKIP skips this tagitem, and the next number of tagitems as
indicated in the tag's ti_Data field.

Inputs

tagListPtr - Pointer to an element in a taglist.

Result

Next tag item or NULL if you reached the end of the list.

Notes

- TAG_MORE works like "go on with new list" instead of "read new
  list and go on with the current one".

PackBoolTags()

Synopsis

ULONG PackBoolTags(
         ULONG initialFlags,
         struct TagItem * tagList,
         struct TagItem * boolMap );

ULONG PackBoolTagsTags(
         ULONG initialFlags,
         struct TagItem * tagList,
         TAG tag, ... );

Function

Scans through the list tagList to find the tags which are contained
in the list boolMap which are then converted to a bit-flag
representation as defined in boolMap.

If the value of the Tag's data is 0, then the boolean value of the
tag is defined as false, otherwise it is true.

Inputs

initialFlags -  an initial set of bit-flags which will be changed
                by this function.

tagList      -  A TagItem list which contains some tags which are
                defined as boolean by having a corresponding tag
                in boolMap. The boolean value of tag->ti_Data
                determines whether the bits in the flag are
                TRUE or FALSE.

boolMap      -  A TagItem list containing a series of tags which
                are to be considered Boolean.

Result

flags        -  The value of initialFlags modified by the values
                of the boolean tags defined in boolMap.

Notes

If there is more than one Tag in tagList of a single type. The
last of these tags will determine the value of that bit-flag.

PackStructureTags()

Synopsis

ULONG PackStructureTags(
         APTR pack,
         ULONG          * packTable,
         struct TagItem * tagList );

ULONG PackStructureTagsTags(
         APTR pack,
         ULONG          * packTable,
         TAG tag, ... );

Function

This function will scan through the packTable, and for each TagItem
described in a packTable entry which can be found in the tagList,
the data in the TagItem's ti_Data field will be packed into the
structure as described in the packTable.

Inputs

pack            -   The structure to fill in.
packTable       -   Table describing how to pack the structure.
                    See the include file utility/pack.h for
                    information on the format of this table.
tagList         -   List of TagItems containing data.

Result

The number of TagItems packed.

RefreshTagItemClones()

Synopsis

void RefreshTagItemClones(
         struct TagItem * clone,
         const struct TagItem * original );

void RefreshTagItemClonesTags(
         struct TagItem * clone,
         TAG tag, ... );

Function

If (and only if) the Tag list 'clone' was created by calling
CloneTagItems on the Tag list 'original', and the list original
has NOT been changed in any way, then this function will change
the list 'clone' back to its original state.

Inputs

original    - The source TagList (unaltered)
clone       - The destination TagList (MUST be allocated by
                CloneTagItems())

Result

The second TagList now has the same values as the first.

Example

struct TagItem *orig, clone;

\* TagList orig has some values already *\
clone = CloneTagList( orig );

\* In between here we do something to the TagItems in clone,
    but we need to have them restored.
*\

RefreshTagItemClones( clone, orig );

Notes

If either of the inputs is NULL, then the function will not do
anything.

Bugs

None, however if either of the two pre-conditions is not fulfilled
then this function will probably be unreliable, or trash memory.

We warned you...

ReleaseNamedObject()

Synopsis

void ReleaseNamedObject(
         struct NamedObject * object );

Function

Releases a NamedObject that you previously obtained by calling
FindNamedObject.

Inputs

object      -   The NamedObject to release.

Result

The NamedObject will be released from your possession, and if it
is ready to be deallocated, then the NamedObject will be freed.

Example

struct NamedObject *nObj, *myNameSpace;

if( nObj = FindNamedObject( myNameSpace, "Some Name", NULL ) )
{
    \*
        Here you do whatever you want. However The NamedObject
        structure should generally be treated READ-ONLY
    *\

    ReleaseNamedObject( nObj );
}

Notes

WARNING: You really should actually have found the NamedObject
    first (that is with FindNamedObject()) before calling this
    function. Failure to take heed of this will cause memory
    use problems.

RemNamedObject()

Synopsis

void RemNamedObject(
         struct NamedObject * object,
         struct Message     * message );

Function

Remove a NamedObject from a namespace.

If the NamedObject cannot be removed at the time of this call, then
the call will return without removing the NamedObject. It will
mark the NamedObject as "waiting for removal".

When the NamedObject is ready to be freed, the supplied message
will be ReplyMsg()'d with the message->mn_Node.ln_Name field
containing either:
    - the address of the NamedObject that was removed. In this case
      you can free the NamedObject yourself.
    - NULL. In this case, another Task has freed the NamedObject,
      and you should not do so.

Inputs

object      -   The NamedObject to attempt to remove.
message     -   The message to send. This message is a standard
                Exec Message, which MUST have the mn_ReplyPort
                field correctly set. The mn_Node.ln_Name field
                will contain the address of the NamedObject or NULL
                upon arrival at your port.

Result

The NamedObject will be removed if possible, or marked for removal
at the next best moment.

Notes

Since this function effectively does a ReleaseNamedObject(), you
must have found this object first.

SDivMod32()

Synopsis

QUAD SDivMod32(
         LONG dividend,
         LONG divisor );

Function

Calculates the 32-bit signed division of dividend by divisor. That
is dividend / divisor. Will return both the quotient and the
remainder.

Inputs

dividend    -   The number to divide.
divisor     -   The to divide by.

Result

For m68k assembly programmers:
    D0: quotient
    D1: remainder
Others:
    The quotient is returned in the high 32 bits of the result.
    The remainder in the low 32 bits.

Notes

The utility.library math functions are unlike all other utility
functions in that they don't require the library base to be
loaded in register A6, and they also save the values of the
address registers A0/A1.

This function is mainly to support assembly programers, and is
probably of limited use to higher-level language programmers.

Bugs

It is very hard for a C programmer to obtain the value of the
remainder. In fact, its pretty near impossible.

SetMem()

Synopsis

APTR SetMem(
         APTR destination,
         UBYTE c,
         LONG length );

Function

Fill a memory block with a Byte.

Inputs

destination - address where the filling starts
c           - value to be filled in
length      - number of Bytes to be filled in

Result

The destination address

Example

SetMem(addr, 10, 100);

SMult32()

Synopsis

LONG SMult32(
         LONG arg1,
         LONG arg2 );

Function

Performs the signed 32-bit multiplication of arg1 * arg2 and
returns a signed 32 bit value.

Inputs

arg1, arg2  -   32 bit signed longs

Result

arg1 * arg2

Example

LONG a = 352543;
LONG b = -52464;
LONG c = SMult32(a,b);
c == -1315946768

Notes

This can perform the multiplication either using the machines
native instructions (if they exist), or in software using a
simple algorithm based on expanding algebraic products.

The utility.library math functions are unlike all other utility
functions in that they don't require the library base to be
loaded in register A6, and they also save the values of the
address registers A0/A1.

This function is mainly to support assembly programers, and is
probably of limited use to higher-level language programmers.

Bugs

Of limited use to C programmers.

SMult64()

Synopsis

QUAD SMult64(
         LONG arg1,
         LONG arg2 );

Function

Compute the signed 64-bit product of arg1 * arg2.

Inputs

arg1, arg2  -   32 bit signed numbers.

Result

arg1 * arg2

Notes

For m68k assembly programmers, QUADs are returned in D0:D1 (with
the high 32 bits in D0).

The utility.library math functions are unlike all other utility
functions in that they don't require the library base to be
loaded in register A6, and they also save the values of the
address registers A0/A1.

This function is mainly to support assembly programers, and is
probably of limited use to higher-level language programmers.

Stricmp()

Synopsis

LONG Stricmp(
         CONST_STRPTR string1,
         CONST_STRPTR string2 );

Function

Compares two strings treating lower and upper case characters
as identical.

Inputs

string1, string2 - The strings to compare.

Result

<0  if string1 <  string2
==0 if string1 == string2
>0  if string1 >  string2

Strlcat()

Synopsis

LONG Strlcat(
         STRPTR destination,
         CONST_STRPTR source,
         LONG size );

Function

Appends the string 'source' to the string 'destination'. The total length
including the terminating NUL is limited to 'size'.

Inputs

destination - the target string. Might be NULL.
source - the string which will be appended. Might be NULL.
size - the length of the 'destination' buffer

Result

The number of Bytes which would have been written without the truncation.

Example

Strlcpy(buffer, "Hello ", sizeof buffer);
Strlcat(buffer, "World.", sizeof buffer);

Strlcpy()

Synopsis

LONG Strlcpy(
         STRPTR destination,
         CONST_STRPTR source,
         LONG size );

Function

Copies the string 'source' into 'destination'. String will be
null-terminated. Not more than 'size' Bytes will be written.

Inputs

destination - the target. Might be NULL.
source      - the string which will be copied. Might be NULL.
size        - the size of the 'destination'

Result

The string lenght of 'source'.

Example

Strlcpy(buffer, "Hello", sizeof buffer);

Strnicmp()

Synopsis

LONG Strnicmp(
         CONST_STRPTR string1,
         CONST_STRPTR string2,
         LONG length );

Function

Compares two strings treating lower and upper case characters
as identical up to a given maximum number of characters.

Inputs

string1, string2 - The strings to compare.
length           - maximum number of characters to compare.

Result

<0  if string1 <  string2
==0 if string1 == string2
>0  if string1 >  string2

TagInArray()

Synopsis

BOOL TagInArray(
         Tag tagValue,
         Tag * tagArray );

Function

Determines whether the value tagValue exists in an array of Tags
pointed to by tagArray. This array must be contiguous, and must be
terminated by TAG_DONE.

This is an array of Tags (ie: Tag tagArray[]), not an array of
TagItems (ie: struct TagItem tagArray[]).

Inputs

tagValue    -   The value of the Tag to search for.
tagArray    -   The ARRAY of Tag's to scan through.

Result

TRUE    if tagValue exists in tagArray
FALSE   otherwise

ToLower()

Synopsis

UBYTE ToLower(
         ULONG character );

Function

Convert a character to lower case.

Inputs

character - The character to convert.

Result

Equivalent lower case character.

ToUpper()

Synopsis

UBYTE ToUpper(
         ULONG character );

Function

Convert a character to uppercase

Inputs

character   - The character that you want changed.

Result

The uppercase version of that character.

Example

STRPTR string; UBYTE chr;

\* Convert a string to uppercase *\
while( chr = *string )
{
    *string = ToUpper( chr );
    string++;
}

Notes

Currently only works for ASCII characters. Would not be difficult
to adapt for other character sets (Unicode for example).

This function is patched by the locale.library, so you should be
prepared for different results when running under different
languages.

UDivMod32()

Synopsis

ULONG UDivMod32(
         ULONG dividend,
         ULONG divisor );

Function

Perform the 32 bit unsigned division and modulus of dividend by
divisor, that is dividend / divisor. Will return both the
quotient and the remainder.

Inputs

dividend        -   The number to divide into (numerator).
divisor         -   The number to divide by (denominator).

Result

For m68k assembly programmers,
    D0: quotient
    D1: remainder

For HLL programmers,
    the quotient

Notes

The utility.library math functions are unlike all other utility
functions in that they don't require the library base to be
loaded in register A6, and they also save the values of the
address registers A0/A1.

This function is mainly to support assembly programers, and is
probably of limited use to higher-level language programmers.

Bugs

It is impossible for C programmers to obtain the value of
remainder.

UMult32()

Synopsis

ULONG UMult32(
         ULONG arg1,
         ULONG arg2 );

Function

Performs an unsigned 32-bit multiplication of arg1 * arg2 and
returns a 32 bit value.

Inputs

arg1, arg2  -   32 bit unsigned longs

Result

arg1 * arg2

Example

LONG a = 352543;
LONG b = 52464;
LONG c = UMult32(a,b);
c == 1315946768

Notes

This can perform the multiplication either using the machines
native instructions (if they exist), or in software using a
simple algorithm (three multiplications, two shifts and
an addition.

The utility.library math functions are unlike all other utility
functions in that they don't require the library base to be
loaded in register A6, and they also save the values of the
address registers A0/A1.

This function is mainly to support assembly programers, and is
probably of limited use to higher-level language programmers.

UMult64()

Synopsis

UQUAD UMult64(
         ULONG arg1,
         ULONG arg2 );

Function

Compute the unsigned 64-bit product of arg1 * arg2.

Inputs

arg1, arg2  -   32 bit unsigned numbers.

Result

arg1 * arg2

Notes

For m68k assembly programmers, UQUADs are returned in D0:D1 (with
the high 32 bits in D0.

This function is really only for people programming in
assembly on real Amigas. Most compilers will be able to do this
math for you inline.

UnpackStructureTags()

Synopsis

ULONG UnpackStructureTags(
         APTR pack,
         ULONG          * packTable,
         struct TagItem * tagList );

ULONG UnpackStructureTagsTags(
         APTR pack,
         ULONG          * packTable,
         TAG tag, ... );

Function

For each table entry, if the matching tag is found in the tagList,
then the data in the structure will be placed in the memory pointed
to by the tags ti_Data.

Note: The value contained in ti_Data must be a *POINTER* to a
      IPTR.

Inputs

pack            -   Pointer to the memory area to be unpacked.
packTable       -   Table describing the unpacking operation.
                    See the include file <utility/pack.h> for
                    more information on this table.
tagList         -   List of TagItems to unpack into.

Result

The number of Tags unpacked.

Notes

PSTF_EXISTS has no effect on this function.

VSNPrintf()

Synopsis

LONG VSNPrintf(
         STRPTR buffer,
         LONG buffer_size,
         CONST_STRPTR format,
         RAWARG args );

Function

Formatted output to a buffer. Maximal buffer_size characters
are written including the trainling zero. The string will be
null-terminated.

Inputs

buffer      - where the string will be written. Might be NULL. In
              that case the required size will still be returnend.

buffer_size - the size of the buffer. Must be at least 1.
format      - the format specification
args        - the arguments which will be filled in

Result

The number of characters which would have been written without
the buffer_size limitation. The trailing zero is included.

Example

TEXT buffer[12];
IPTR args[2];
args[0] = (IPTR)"XYZ";
args[1] = 12345;
LONG count = VSNPrintf(buffer, sizeof buffer, "ab%scd%ldef", (RAWARG)args);

Notes

The same rules as for RawDoFmt() are valid for format and args.

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