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6.5.4 The iconv Implementation in the GNU C Library

After reading about the problems of iconv implementations in the last section it is certainly good to note that the implementation in the GNU C Library has none of the problems mentioned above. What follows is a step-by-step analysis of the points raised above. The evaluation is based on the current state of the development (as of January 1999). The development of the iconv functions is not complete, but basic functionality has solidified.

The GNU C Library’s iconv implementation uses shared loadable modules to implement the conversions. A very small number of conversions are built into the library itself but these are only rather trivial conversions.

All the benefits of loadable modules are available in the GNU C Library implementation. This is especially appealing since the interface is well documented (see below), and it, therefore, is easy to write new conversion modules. The drawback of using loadable objects is not a problem in the GNU C Library, at least on ELF systems. Since the library is able to load shared objects even in statically linked binaries, static linking need not be forbidden in case one wants to use iconv.

The second mentioned problem is the number of supported conversions. Currently, the GNU C Library supports more than 150 character sets. The way the implementation is designed the number of supported conversions is greater than 22350 (150 times 149). If any conversion from or to a character set is missing, it can be added easily.

Particularly impressive as it may be, this high number is due to the fact that the GNU C Library implementation of iconv does not have the third problem mentioned above (i.e., whenever there is a conversion from a character set A to B and from B to C it is always possible to convert from A to C directly). If the iconv_open returns an error and sets errno to EINVAL, there is no known way, directly or indirectly, to perform the wanted conversion.

Triangulation is achieved by providing for each character set a conversion from and to UCS-4 encoded ISO 10646. Using ISO 10646 as an intermediate representation it is possible to triangulate (i.e., convert with an intermediate representation).

There is no inherent requirement to provide a conversion to ISO 10646 for a new character set, and it is also possible to provide other conversions where neither source nor destination character set is ISO 10646. The existing set of conversions is simply meant to cover all conversions that might be of interest.

All currently available conversions use the triangulation method above, making conversion run unnecessarily slow. If, for example, somebody often needs the conversion from ISO-2022-JP to EUC-JP, a quicker solution would involve direct conversion between the two character sets, skipping the input to ISO 10646 first. The two character sets of interest are much more similar to each other than to ISO 10646.

In such a situation one easily can write a new conversion and provide it as a better alternative. The GNU C Library iconv implementation would automatically use the module implementing the conversion if it is specified to be more efficient.

6.5.4.1 Format of gconv-modules files

All information about the available conversions comes from a file named gconv-modules, which can be found in any of the directories along the GCONV_PATH. The gconv-modules files are line-oriented text files, where each of the lines has one of the following formats:

Returning to the example above where one has written a module to directly convert from ISO-2022-JP to EUC-JP and back. All that has to be done is to put the new module, let its name be ISO2022JP-EUCJP.so, in a directory and add a file gconv-modules with the following content in the same directory:

module  ISO-2022-JP//   EUC-JP//        ISO2022JP-EUCJP    1
module  EUC-JP//        ISO-2022-JP//   ISO2022JP-EUCJP    1

To see why this is sufficient, it is necessary to understand how the conversion used by iconv (and described in the descriptor) is selected. The approach to this problem is quite simple.

At the first call of the iconv_open function the program reads all available gconv-modules files and builds up two tables: one containing all the known aliases and another that contains the information about the conversions and which shared object implements them.

6.5.4.2 Finding the conversion path in iconv

The set of available conversions form a directed graph with weighted edges. The weights on the edges are the costs specified in the gconv-modules files. The iconv_open function uses an algorithm suitable for search for the best path in such a graph and so constructs a list of conversions that must be performed in succession to get the transformation from the source to the destination character set.

Explaining why the above gconv-modules files allows the iconv implementation to resolve the specific ISO-2022-JP to EUC-JP conversion module instead of the conversion coming with the library itself is straightforward. Since the latter conversion takes two steps (from ISO-2022-JP to ISO 10646 and then from ISO 10646 to EUC-JP), the cost is 1+1 = 2. The above gconv-modules file, however, specifies that the new conversion modules can perform this conversion with only the cost of 1.

A mysterious item about the gconv-modules file above (and also the file coming with the GNU C Library) are the names of the character sets specified in the module lines. Why do almost all the names end in //? And this is not all: the names can actually be regular expressions. At this point in time this mystery should not be revealed, unless you have the relevant spell-casting materials: ashes from an original DOS 6.2 boot disk burnt in effigy, a crucifix blessed by St. Emacs, assorted herbal roots from Central America, sand from Cebu, etc. Sorry! The part of the implementation where this is used is not yet finished. For now please simply follow the existing examples. It’ll become clearer once it is. –drepper

A last remark about the gconv-modules is about the names not ending with //. A character set named INTERNAL is often mentioned. From the discussion above and the chosen name it should have become clear that this is the name for the representation used in the intermediate step of the triangulation. We have said that this is UCS-4 but actually that is not quite right. The UCS-4 specification also includes the specification of the byte ordering used. Since a UCS-4 value consists of four bytes, a stored value is affected by byte ordering. The internal representation is not the same as UCS-4 in case the byte ordering of the processor (or at least the running process) is not the same as the one required for UCS-4. This is done for performance reasons as one does not want to perform unnecessary byte-swapping operations if one is not interested in actually seeing the result in UCS-4. To avoid trouble with endianness, the internal representation consistently is named INTERNAL even on big-endian systems where the representations are identical.

6.5.4.3 iconv module data structures

So far this section has described how modules are located and considered to be used. What remains to be described is the interface of the modules so that one can write new ones. This section describes the interface as it is in use in January 1999. The interface will change a bit in the future but, with luck, only in an upwardly compatible way.

The definitions necessary to write new modules are publicly available in the non-standard header gconv.h. The following text, therefore, describes the definitions from this header file. First, however, it is necessary to get an overview.

From the perspective of the user of iconv the interface is quite simple: the iconv_open function returns a handle that can be used in calls to iconv, and finally the handle is freed with a call to iconv_close. The problem is that the handle has to be able to represent the possibly long sequences of conversion steps and also the state of each conversion since the handle is all that is passed to the iconv function. Therefore, the data structures are really the elements necessary to understanding the implementation.

We need two different kinds of data structures. The first describes the conversion and the second describes the state etc. There are really two type definitions like this in gconv.h.

Data type: struct __gconv_step

This data structure describes one conversion a module can perform. For each function in a loaded module with conversion functions there is exactly one object of this type. This object is shared by all users of the conversion (i.e., this object does not contain any information corresponding to an actual conversion; it only describes the conversion itself).

struct __gconv_loaded_object *__shlib_handle
const char *__modname
int __counter

All these elements of the structure are used internally in the C library to coordinate loading and unloading the shared. One must not expect any of the other elements to be available or initialized.

const char *__from_name
const char *__to_name

__from_name and __to_name contain the names of the source and destination character sets. They can be used to identify the actual conversion to be carried out since one module might implement conversions for more than one character set and/or direction.

gconv_fct __fct
gconv_init_fct __init_fct
gconv_end_fct __end_fct

These elements contain pointers to the functions in the loadable module. The interface will be explained below.

int __min_needed_from
int __max_needed_from
int __min_needed_to
int __max_needed_to;

These values have to be supplied in the init function of the module. The __min_needed_from value specifies how many bytes a character of the source character set at least needs. The __max_needed_from specifies the maximum value that also includes possible shift sequences.

The __min_needed_to and __max_needed_to values serve the same purpose as __min_needed_from and __max_needed_from but this time for the destination character set.

It is crucial that these values be accurate since otherwise the conversion functions will have problems or not work at all.

int __stateful

This element must also be initialized by the init function. int __stateful is nonzero if the source character set is stateful. Otherwise it is zero.

void *__data

This element can be used freely by the conversion functions in the module. void *__data can be used to communicate extra information from one call to another. void *__data need not be initialized if not needed at all. If void *__data element is assigned a pointer to dynamically allocated memory (presumably in the init function) it has to be made sure that the end function deallocates the memory. Otherwise the application will leak memory.

It is important to be aware that this data structure is shared by all users of this specification conversion and therefore the __data element must not contain data specific to one specific use of the conversion function.

Data type: struct __gconv_step_data

This is the data structure that contains the information specific to each use of the conversion functions.

char *__outbuf
char *__outbufend

These elements specify the output buffer for the conversion step. The __outbuf element points to the beginning of the buffer, and __outbufend points to the byte following the last byte in the buffer. The conversion function must not assume anything about the size of the buffer but it can be safely assumed the there is room for at least one complete character in the output buffer.

Once the conversion is finished, if the conversion is the last step, the __outbuf element must be modified to point after the last byte written into the buffer to signal how much output is available. If this conversion step is not the last one, the element must not be modified. The __outbufend element must not be modified.

int __is_last

This element is nonzero if this conversion step is the last one. This information is necessary for the recursion. See the description of the conversion function internals below. This element must never be modified.

int __invocation_counter

The conversion function can use this element to see how many calls of the conversion function already happened. Some character sets require a certain prolog when generating output, and by comparing this value with zero, one can find out whether it is the first call and whether, therefore, the prolog should be emitted. This element must never be modified.

int __internal_use

This element is another one rarely used but needed in certain situations. It is assigned a nonzero value in case the conversion functions are used to implement mbsrtowcs et.al. (i.e., the function is not used directly through the iconv interface).

This sometimes makes a difference as it is expected that the iconv functions are used to translate entire texts while the mbsrtowcs functions are normally used only to convert single strings and might be used multiple times to convert entire texts.

But in this situation we would have problem complying with some rules of the character set specification. Some character sets require a prolog, which must appear exactly once for an entire text. If a number of mbsrtowcs calls are used to convert the text, only the first call must add the prolog. However, because there is no communication between the different calls of mbsrtowcs, the conversion functions have no possibility to find this out. The situation is different for sequences of iconv calls since the handle allows access to the needed information.

The int __internal_use element is mostly used together with __invocation_counter as follows:

if (!data->__internal_use
     && data->__invocation_counter == 0)
  /* Emit prolog.  */
  …

This element must never be modified.

mbstate_t *__statep

The __statep element points to an object of type mbstate_t (see Keeping the state). The conversion of a stateful character set must use the object pointed to by __statep to store information about the conversion state. The __statep element itself must never be modified.

mbstate_t __state

This element must never be used directly. It is only part of this structure to have the needed space allocated.

6.5.4.4 iconv module interfaces

With the knowledge about the data structures we now can describe the conversion function itself. To understand the interface a bit of knowledge is necessary about the functionality in the C library that loads the objects with the conversions.

It is often the case that one conversion is used more than once (i.e., there are several iconv_open calls for the same set of character sets during one program run). The mbsrtowcs et.al. functions in the GNU C Library also use the iconv functionality, which increases the number of uses of the same functions even more.

Because of this multiple use of conversions, the modules do not get loaded exclusively for one conversion. Instead a module once loaded can be used by an arbitrary number of iconv or mbsrtowcs calls at the same time. The splitting of the information between conversion- function-specific information and conversion data makes this possible. The last section showed the two data structures used to do this.

This is of course also reflected in the interface and semantics of the functions that the modules must provide. There are three functions that must have the following names:

gconv_init

The gconv_init function initializes the conversion function specific data structure. This very same object is shared by all conversions that use this conversion and, therefore, no state information about the conversion itself must be stored in here. If a module implements more than one conversion, the gconv_init function will be called multiple times.

gconv_end

The gconv_end function is responsible for freeing all resources allocated by the gconv_init function. If there is nothing to do, this function can be missing. Special care must be taken if the module implements more than one conversion and the gconv_init function does not allocate the same resources for all conversions.

gconv

This is the actual conversion function. It is called to convert one block of text. It gets passed the conversion step information initialized by gconv_init and the conversion data, specific to this use of the conversion functions.

There are three data types defined for the three module interface functions and these define the interface.

Data type: int (*__gconv_init_fct) (struct __gconv_step *)

This specifies the interface of the initialization function of the module. It is called exactly once for each conversion the module implements.

As explained in the description of the struct __gconv_step data structure above the initialization function has to initialize parts of it.

__min_needed_from
__max_needed_from
__min_needed_to
__max_needed_to

These elements must be initialized to the exact numbers of the minimum and maximum number of bytes used by one character in the source and destination character sets, respectively. If the characters all have the same size, the minimum and maximum values are the same.

__stateful

This element must be initialized to a nonzero value if the source character set is stateful. Otherwise it must be zero.

If the initialization function needs to communicate some information to the conversion function, this communication can happen using the __data element of the __gconv_step structure. But since this data is shared by all the conversions, it must not be modified by the conversion function. The example below shows how this can be used.

#define MIN_NEEDED_FROM         1
#define MAX_NEEDED_FROM         4
#define MIN_NEEDED_TO           4
#define MAX_NEEDED_TO           4

int
gconv_init (struct __gconv_step *step)
{
  /* Determine which direction.  */
  struct iso2022jp_data *new_data;
  enum direction dir = illegal_dir;
  enum variant var = illegal_var;
  int result;

  if (__strcasecmp (step->__from_name, "ISO-2022-JP//") == 0)
    {
      dir = from_iso2022jp;
      var = iso2022jp;
    }
  else if (__strcasecmp (step->__to_name, "ISO-2022-JP//") == 0)
    {
      dir = to_iso2022jp;
      var = iso2022jp;
    }
  else if (__strcasecmp (step->__from_name, "ISO-2022-JP-2//") == 0)
    {
      dir = from_iso2022jp;
      var = iso2022jp2;
    }
  else if (__strcasecmp (step->__to_name, "ISO-2022-JP-2//") == 0)
    {
      dir = to_iso2022jp;
      var = iso2022jp2;
    }

  result = __GCONV_NOCONV;
  if (dir != illegal_dir)
    {
      new_data = (struct iso2022jp_data *)
        malloc (sizeof (struct iso2022jp_data));

      result = __GCONV_NOMEM;
      if (new_data != NULL)
        {
          new_data->dir = dir;
          new_data->var = var;
          step->__data = new_data;

          if (dir == from_iso2022jp)
            {
              step->__min_needed_from = MIN_NEEDED_FROM;
              step->__max_needed_from = MAX_NEEDED_FROM;
              step->__min_needed_to = MIN_NEEDED_TO;
              step->__max_needed_to = MAX_NEEDED_TO;
            }
          else
            {
              step->__min_needed_from = MIN_NEEDED_TO;
              step->__max_needed_from = MAX_NEEDED_TO;
              step->__min_needed_to = MIN_NEEDED_FROM;
              step->__max_needed_to = MAX_NEEDED_FROM + 2;
            }

          /* Yes, this is a stateful encoding.  */
          step->__stateful = 1;

          result = __GCONV_OK;
        }
    }

  return result;
}

The function first checks which conversion is wanted. The module from which this function is taken implements four different conversions; which one is selected can be determined by comparing the names. The comparison should always be done without paying attention to the case.

Next, a data structure, which contains the necessary information about which conversion is selected, is allocated. The data structure struct iso2022jp_data is locally defined since, outside the module, this data is not used at all. Please note that if all four conversions this modules supports are requested there are four data blocks.

One interesting thing is the initialization of the __min_ and __max_ elements of the step data object. A single ISO-2022-JP character can consist of one to four bytes. Therefore the MIN_NEEDED_FROM and MAX_NEEDED_FROM macros are defined this way. The output is always the INTERNAL character set (aka UCS-4) and therefore each character consists of exactly four bytes. For the conversion from INTERNAL to ISO-2022-JP we have to take into account that escape sequences might be necessary to switch the character sets. Therefore the __max_needed_to element for this direction gets assigned MAX_NEEDED_FROM + 2. This takes into account the two bytes needed for the escape sequences to single the switching. The asymmetry in the maximum values for the two directions can be explained easily: when reading ISO-2022-JP text, escape sequences can be handled alone (i.e., it is not necessary to process a real character since the effect of the escape sequence can be recorded in the state information). The situation is different for the other direction. Since it is in general not known which character comes next, one cannot emit escape sequences to change the state in advance. This means the escape sequences that have to be emitted together with the next character. Therefore one needs more room than only for the character itself.

The possible return values of the initialization function are:

__GCONV_OK

The initialization succeeded

__GCONV_NOCONV

The requested conversion is not supported in the module. This can happen if the gconv-modules file has errors.

__GCONV_NOMEM

Memory required to store additional information could not be allocated.

The function called before the module is unloaded is significantly easier. It often has nothing at all to do; in which case it can be left out completely.

Data type: void (*__gconv_end_fct) (struct gconv_step *)

The task of this function is to free all resources allocated in the initialization function. Therefore only the __data element of the object pointed to by the argument is of interest. Continuing the example from the initialization function, the finalization function looks like this:

void
gconv_end (struct __gconv_step *data)
{
  free (data->__data);
}

The most important function is the conversion function itself, which can get quite complicated for complex character sets. But since this is not of interest here, we will only describe a possible skeleton for the conversion function.

Data type: int (*__gconv_fct) (struct __gconv_step *, struct __gconv_step_data *, const char **, const char *, size_t *, int)

The conversion function can be called for two basic reason: to convert text or to reset the state. From the description of the iconv function it can be seen why the flushing mode is necessary. What mode is selected is determined by the sixth argument, an integer. This argument being nonzero means that flushing is selected.

Common to both modes is where the output buffer can be found. The information about this buffer is stored in the conversion step data. A pointer to this information is passed as the second argument to this function. The description of the struct __gconv_step_data structure has more information on the conversion step data.

What has to be done for flushing depends on the source character set. If the source character set is not stateful, nothing has to be done. Otherwise the function has to emit a byte sequence to bring the state object into the initial state. Once this all happened the other conversion modules in the chain of conversions have to get the same chance. Whether another step follows can be determined from the __is_last element of the step data structure to which the first parameter points.

The more interesting mode is when actual text has to be converted. The first step in this case is to convert as much text as possible from the input buffer and store the result in the output buffer. The start of the input buffer is determined by the third argument, which is a pointer to a pointer variable referencing the beginning of the buffer. The fourth argument is a pointer to the byte right after the last byte in the buffer.

The conversion has to be performed according to the current state if the character set is stateful. The state is stored in an object pointed to by the __statep element of the step data (second argument). Once either the input buffer is empty or the output buffer is full the conversion stops. At this point, the pointer variable referenced by the third parameter must point to the byte following the last processed byte (i.e., if all of the input is consumed, this pointer and the fourth parameter have the same value).

What now happens depends on whether this step is the last one. If it is the last step, the only thing that has to be done is to update the __outbuf element of the step data structure to point after the last written byte. This update gives the caller the information on how much text is available in the output buffer. In addition, the variable pointed to by the fifth parameter, which is of type size_t, must be incremented by the number of characters (not bytes) that were converted in a non-reversible way. Then, the function can return.

In case the step is not the last one, the later conversion functions have to get a chance to do their work. Therefore, the appropriate conversion function has to be called. The information about the functions is stored in the conversion data structures, passed as the first parameter. This information and the step data are stored in arrays, so the next element in both cases can be found by simple pointer arithmetic:

int
gconv (struct __gconv_step *step, struct __gconv_step_data *data,
       const char **inbuf, const char *inbufend, size_t *written,
       int do_flush)
{
  struct __gconv_step *next_step = step + 1;
  struct __gconv_step_data *next_data = data + 1;
  …

The next_step pointer references the next step information and next_data the next data record. The call of the next function therefore will look similar to this:

  next_step->__fct (next_step, next_data, &outerr, outbuf,
                    written, 0)

But this is not yet all. Once the function call returns the conversion function might have some more to do. If the return value of the function is __GCONV_EMPTY_INPUT, more room is available in the output buffer. Unless the input buffer is empty the conversion, functions start all over again and process the rest of the input buffer. If the return value is not __GCONV_EMPTY_INPUT, something went wrong and we have to recover from this.

A requirement for the conversion function is that the input buffer pointer (the third argument) always point to the last character that was put in converted form into the output buffer. This is trivially true after the conversion performed in the current step, but if the conversion functions deeper downstream stop prematurely, not all characters from the output buffer are consumed and, therefore, the input buffer pointers must be backed off to the right position.

Correcting the input buffers is easy to do if the input and output character sets have a fixed width for all characters. In this situation we can compute how many characters are left in the output buffer and, therefore, can correct the input buffer pointer appropriately with a similar computation. Things are getting tricky if either character set has characters represented with variable length byte sequences, and it gets even more complicated if the conversion has to take care of the state. In these cases the conversion has to be performed once again, from the known state before the initial conversion (i.e., if necessary the state of the conversion has to be reset and the conversion loop has to be executed again). The difference now is that it is known how much input must be created, and the conversion can stop before converting the first unused character. Once this is done the input buffer pointers must be updated again and the function can return.

One final thing should be mentioned. If it is necessary for the conversion to know whether it is the first invocation (in case a prolog has to be emitted), the conversion function should increment the __invocation_counter element of the step data structure just before returning to the caller. See the description of the struct __gconv_step_data structure above for more information on how this can be used.

The return value must be one of the following values:

__GCONV_EMPTY_INPUT

All input was consumed and there is room left in the output buffer.

__GCONV_FULL_OUTPUT

No more room in the output buffer. In case this is not the last step this value is propagated down from the call of the next conversion function in the chain.

__GCONV_INCOMPLETE_INPUT

The input buffer is not entirely empty since it contains an incomplete character sequence.

The following example provides a framework for a conversion function. In case a new conversion has to be written the holes in this implementation have to be filled and that is it.

int
gconv (struct __gconv_step *step, struct __gconv_step_data *data,
       const char **inbuf, const char *inbufend, size_t *written,
       int do_flush)
{
  struct __gconv_step *next_step = step + 1;
  struct __gconv_step_data *next_data = data + 1;
  gconv_fct fct = next_step->__fct;
  int status;

  /* If the function is called with no input this means we have
     to reset to the initial state.  The possibly partly
     converted input is dropped.  */
  if (do_flush)
    {
      status = __GCONV_OK;

      /* Possible emit a byte sequence which put the state object
         into the initial state.  */

      /* Call the steps down the chain if there are any but only
         if we successfully emitted the escape sequence.  */
      if (status == __GCONV_OK && ! data->__is_last)
        status = fct (next_step, next_data, NULL, NULL,
                      written, 1);
    }
  else
    {
      /* We preserve the initial values of the pointer variables.  */
      const char *inptr = *inbuf;
      char *outbuf = data->__outbuf;
      char *outend = data->__outbufend;
      char *outptr;

      do
        {
          /* Remember the start value for this round.  */
          inptr = *inbuf;
          /* The outbuf buffer is empty.  */
          outptr = outbuf;

          /* For stateful encodings the state must be safe here.  */

          /* Run the conversion loop.  status is set
             appropriately afterwards.  */

          /* If this is the last step, leave the loop.  There is
             nothing we can do.  */
          if (data->__is_last)
            {
              /* Store information about how many bytes are
                 available.  */
              data->__outbuf = outbuf;

             /* If any non-reversible conversions were performed,
                add the number to *written.  */

             break;
           }

          /* Write out all output that was produced.  */
          if (outbuf > outptr)
            {
              const char *outerr = data->__outbuf;
              int result;

              result = fct (next_step, next_data, &outerr,
                            outbuf, written, 0);

              if (result != __GCONV_EMPTY_INPUT)
                {
                  if (outerr != outbuf)
                    {
                      /* Reset the input buffer pointer.  We
                         document here the complex case.  */
                      size_t nstatus;

                      /* Reload the pointers.  */
                      *inbuf = inptr;
                      outbuf = outptr;

                      /* Possibly reset the state.  */

                      /* Redo the conversion, but this time
                         the end of the output buffer is at
                         outerr.  */
                    }

                  /* Change the status.  */
                  status = result;
                }
              else
                /* All the output is consumed, we can make
                    another run if everything was ok.  */
                if (status == __GCONV_FULL_OUTPUT)
                  status = __GCONV_OK;
           }
        }
      while (status == __GCONV_OK);

      /* We finished one use of this step.  */
      ++data->__invocation_counter;
    }

  return status;
}

This information should be sufficient to write new modules. Anybody doing so should also take a look at the available source code in the GNU C Library sources. It contains many examples of working and optimized modules.


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