ref: 420663d47790a7e34a1662d679a0c00efdb5b7e5
dir: /devel.but/
\cfg{text-indent}{0} \cfg{text-width}{72} \cfg{text-title-align}{left} \cfg{text-chapter-align}{left} \cfg{text-chapter-numeric}{true} \cfg{text-chapter-suffix}{. } \cfg{text-chapter-underline}{-} \cfg{text-section-align}{0}{left} \cfg{text-section-numeric}{0}{true} \cfg{text-section-suffix}{0}{. } \cfg{text-section-underline}{0}{-} \cfg{text-section-align}{1}{left} \cfg{text-section-numeric}{1}{true} \cfg{text-section-suffix}{1}{. } \cfg{text-section-underline}{1}{-} \cfg{text-versionid}{0} \cfg{html-contents-filename}{index.html} \cfg{html-template-filename}{%k.html} \cfg{html-index-filename}{docindex.html} \cfg{html-leaf-level}{1} \cfg{html-contents-depth-0}{1} \cfg{html-contents-depth-1}{3} \cfg{html-leaf-contains-contents}{true} \define{dash} \u2013{-} \title Developer documentation for Simon Tatham's puzzle collection This is a guide to the internal structure of Simon Tatham's Portable Puzzle Collection (henceforth referred to simply as \q{Puzzles}), for use by anyone attempting to implement a new puzzle or port to a new platform. This guide is believed correct as of \cw{git} commit \cw{a2212e82aa2f4b9a4ee22783d6fed2761c213432}. Hopefully it will be updated along with the code in future, but if not, I've at least left this version number in here so you can figure out what's changed by tracking commit comments from there onwards. \C{intro} Introduction The Puzzles code base is divided into four parts: a set of interchangeable front ends, a set of interchangeable back ends, a universal \q{middle end} which acts as a buffer between the two, and a bunch of miscellaneous utility functions. In the following sections I give some general discussion of each of these parts. \H{intro-frontend} Front end The front end is the non-portable part of the code: it's the bit that you replace completely when you port to a different platform. So it's responsible for all system calls, all GUI interaction, and anything else platform-specific. The front end contains \cw{main()} or the local platform's equivalent. Top-level control over the application's execution flow belongs to the front end (it isn't, for example, a set of functions called by a universal \cw{main()} somewhere else). The front end has complete freedom to design the GUI for any given port of Puzzles. There is no centralised mechanism for maintaining the menu layout, for example. This has a cost in consistency (when I \e{do} want the same menu layout on more than one platform, I have to edit N pieces of code in parallel every time I make a change), but the advantage is that local GUI conventions can be conformed to and local constraints adapted to. For example, MacOS has strict human interface guidelines which specify a different menu layout from the one I've used on Windows and GTK; there's nothing stopping the MacOS front end from providing a menu layout consistent with those guidelines. Although the front end is mostly caller rather than the callee in its interactions with other parts of the code, it is required to implement a small API for other modules to call, mostly of drawing functions for games to use when drawing their graphics. The drawing API is documented in \k{drawing}; the other miscellaneous front end API functions are documented in \k{frontend-api}. \H{intro-backend} Back end A \q{back end}, in this collection, is synonymous with a \q{puzzle}. Each back end implements a different game. At the top level, a back end is simply a data structure, containing a few constants (flag words, preferred pixel size) and a large number of function pointers. Back ends are almost invariably callee rather than caller, which means there's a limitation on what a back end can do on its own initiative. The persistent state in a back end is divided into a number of data structures, which are used for different purposes and therefore likely to be switched around, changed without notice, and otherwise updated by the rest of the code. It is important when designing a back end to put the right pieces of data into the right structures, or standard midend-provided features (such as Undo) may fail to work. The functions and variables provided in the back end data structure are documented in \k{backend}. \H{intro-midend} Middle end Puzzles has a single and universal \q{middle end}. This code is common to all platforms and all games; it sits in between the front end and the back end and provides standard functionality everywhere. People adding new back ends or new front ends should generally not need to edit the middle end. On rare occasions there might be a change that can be made to the middle end to permit a new game to do something not currently anticipated by the middle end's present design; however, this is terribly easy to get wrong and should probably not be undertaken without consulting the primary maintainer (me). Patch submissions containing unannounced mid-end changes will be treated on their merits like any other patch; this is just a friendly warning that mid-end changes will need quite a lot of merits to make them acceptable. Functionality provided by the mid-end includes: \b Maintaining a list of game state structures and moving back and forth along that list to provide Undo and Redo. \b Handling timers (for move animations, flashes on completion, and in some cases actually timing the game). \b Handling the container format of game IDs: receiving them, picking them apart into parameters, description and/or random seed, and so on. The game back end need only handle the individual parts of a game ID (encoded parameters and encoded game description); everything else is handled centrally by the mid-end. \b Handling standard keystrokes and menu commands, such as \q{New Game}, \q{Restart Game} and \q{Quit}. \b Pre-processing mouse events so that the game back ends can rely on them arriving in a sensible order (no missing button-release events, no sudden changes of which button is currently pressed, etc). \b Handling the dialog boxes which ask the user for a game ID. \b Handling serialisation of entire games (for loading and saving a half-finished game to a disk file; for handling application shutdown and restart on platforms such as PalmOS where state is expected to be saved; for storing the previous game in order to undo and redo across a New Game event). Thus, there's a lot of work done once by the mid-end so that individual back ends don't have to worry about it. All the back end has to do is cooperate in ensuring the mid-end can do its work properly. The API of functions provided by the mid-end to be called by the front end is documented in \k{midend}. \H{intro-utils} Miscellaneous utilities In addition to these three major structural components, the Puzzles code also contains a variety of utility modules usable by all of the above components. There is a set of functions to provide platform-independent random number generation; functions to make memory allocation easier; functions which implement a balanced tree structure to be used as necessary in complex algorithms; and a few other miscellaneous functions. All of these are documented in \k{utils}. \H{intro-structure} Structure of this guide There are a number of function call interfaces within Puzzles, and this guide will discuss each one in a chapter of its own. After that, \k{writing} discusses how to design new games, with some general design thoughts and tips. \C{backend} Interface to the back end This chapter gives a detailed discussion of the interface that each back end must implement. At the top level, each back end source file exports a single global symbol, which is a \c{const struct game} containing a large number of function pointers and a small amount of constant data. This structure is called by different names depending on what kind of platform the puzzle set is being compiled on: \b On platforms such as Windows and GTK, which build a separate binary for each puzzle, the game structure in every back end has the same name, \cq{thegame}; the front end refers directly to this name, so that compiling the same front end module against a different back end module builds a different puzzle. \b On platforms such as MacOS X and PalmOS, which build all the puzzles into a single monolithic binary, the game structure in each back end must have a different name, and there's a helper module \c{list.c} which constructs a complete list of those game structures from a header file generated by CMake. On the latter type of platform, source files may assume that the preprocessor symbol \c{COMBINED} has been defined. Thus, the usual code to declare the game structure looks something like this: \c #ifdef COMBINED \c #define thegame net /* or whatever this game is called */ \e iii iiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiii \c #endif \c \c const struct game thegame = { \c /* lots of structure initialisation in here */ \e iiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiii \c }; Game back ends must also internally define a number of data structures, for storing their various persistent state. This chapter will first discuss the nature and use of those structures, and then go on to give details of every element of the game structure. \H{backend-structs} Data structures Each game is required to define four separate data structures. This section discusses each one and suggests what sorts of things need to be put in it. \S{backend-game-params} \c{game_params} The \c{game_params} structure contains anything which affects the automatic generation of new puzzles. So if puzzle generation is parametrised in any way, those parameters need to be stored in \c{game_params}. Most puzzles currently in this collection are played on a grid of squares, meaning that the most obvious parameter is the grid size. Many puzzles have additional parameters; for example, Mines allows you to control the number of mines in the grid independently of its size, Net can be wrapping or non-wrapping, Solo has difficulty levels and symmetry settings, and so on. A simple rule for deciding whether a data item needs to go in \c{game_params} is: would the user expect to be able to control this data item from either the preset-game-types menu or the \q{Custom} game type configuration? If so, it's part of \c{game_params}. \c{game_params} structures are permitted to contain pointers to subsidiary data if they need to. The back end is required to provide functions to create and destroy \c{game_params}, and those functions can allocate and free additional memory if necessary. (It has not yet been necessary to do this in any puzzle so far, but the capability is there just in case.) \c{game_params} is also the only structure which the game's \cw{compute_size()} function may refer to; this means that any aspect of the game which affects the size of the window it needs to be drawn in (other than the magnification level) must be stored in \c{game_params}. In particular, this imposes the fundamental limitation that random game generation may not have a random effect on the window size: game generation algorithms are constrained to work by starting from the grid size rather than generating it as an emergent phenomenon. (Although this is a restriction in theory, it has not yet seemed to be a problem.) \S{backend-game-state} \c{game_state} While the user is actually playing a puzzle, the \c{game_state} structure stores all the data corresponding to the current state of play. The mid-end keeps \c{game_state}s in a list, and adds to the list every time the player makes a move; the Undo and Redo functions step back and forth through that list. Therefore, a good means of deciding whether a data item needs to go in \c{game_state} is: would a player expect that data item to be restored on undo? If so, put it in \c{game_state}, and this will automatically happen without you having to lift a finger. If not, then you might have found a data item that needs to go in \c{game_ui} instead. Two quite different examples of this: \b if the game provides an interface for making moves by moving a cursor around the grid with the keyboard and pressing some other key when you get to a square you want to change, then the location of that cursor belongs in \c{game_ui}, because the player will want to undo one \e{square change} at a time, not one \e{cursor movement} at a time. \b Mines tracks the number of times you opened a mine square and died. Every time you do that, you can only continue the game by pressing Undo. So the deaths counter belongs in \c{game_ui}, because otherwise, it would revert to 0 every time you undid your mistaken move. During play, \c{game_state}s are often passed around without an accompanying \c{game_params} structure. Therefore, any information in \c{game_params} which is important during play (such as the grid size) must be duplicated within the \c{game_state}. One simple method of doing this is to have the \c{game_state} structure \e{contain} a \c{game_params} structure as one of its members, although this isn't obligatory if you prefer to do it another way. \S{backend-game-drawstate} \c{game_drawstate} \c{game_drawstate} carries persistent state relating to the current graphical contents of the puzzle window. The same \c{game_drawstate} is passed to every call to the game redraw function, so that it can remember what it has already drawn and what needs redrawing. A typical use for a \c{game_drawstate} is to have an array mirroring the array of grid squares in the \c{game_state}, but describing what was drawn in the window on the most recent redraw. This is used to identify the squares that need redrawing next time, by deciding what the new value in that array should be, and comparing it to what was drawn last time. See \k{writing-howto-redraw} for more on this subject. \c{game_drawstate} is occasionally completely torn down and reconstructed by the mid-end, if the user somehow forces a full redraw. Therefore, no data should be stored in \c{game_drawstate} which is \e{not} related to the state of the puzzle window, because it might be unexpectedly destroyed. The back end provides functions to create and destroy \c{game_drawstate}, which means it can contain pointers to subsidiary allocated data if it needs to. A common thing to want to allocate in a \c{game_drawstate} is a \c{blitter}; see \k{drawing-blitter} for more on this subject. \S{backend-game-ui} \c{game_ui} \c{game_ui} contains whatever doesn't fit into the above three structures! A new \c{game_ui} is created when the user begins playing a new instance of a puzzle (i.e. during \q{New Game} or after entering a game ID etc). It persists until the user finishes playing that game and begins another one (or closes the window); in particular, \q{Restart Game} does \e{not} destroy the \c{game_ui}. \c{game_ui} is useful for implementing user-interface state which is not part of \c{game_state}. Common examples are keyboard control (you wouldn't want to have to separately Undo through every cursor motion) and mouse dragging. See \k{writing-keyboard-cursor} and \k{writing-howto-dragging}, respectively, for more details. Another use for \c{game_ui} is to store highly persistent data such as the Mines death counter. This is conceptually rather different: where the Net cursor position was \e{not important enough} to preserve for the player to restore by Undo, the Mines death counter is \e{too important} to permit the player to revert by Undo! A final use for \c{game_ui} is to pass information to the redraw function about recent changes to the game state. This is used in Mines, for example, to indicate whether a requested \q{flash} should be a white flash for victory or a red flash for defeat; see \k{writing-flash-types}. \H{backend-simple} Simple data in the back end In this section I begin to discuss each individual element in the back end structure. To begin with, here are some simple self-contained data elements. \S{backend-name} \c{name} \c const char *name; This is a simple ASCII string giving the name of the puzzle. This name will be used in window titles, in game selection menus on monolithic platforms, and anywhere else that the front end needs to know the name of a game. \S{backend-winhelp} \c{winhelp_topic} and \c{htmlhelp_topic} \c const char *winhelp_topic, *htmlhelp_topic; These members are used on Windows only, to provide online help. Although the Windows front end provides a separate binary for each puzzle, it has a single monolithic help file; so when a user selects \q{Help} from the menu, the program needs to open the help file and jump to the chapter describing that particular puzzle. This code base still supports the legacy \cw{.HLP} Windows Help format as well as the less old \cw{.CHM} HTML Help format. The two use different methods of identifying topics, so you have to specify both. Each chapter about a puzzle in \c{puzzles.but} is labelled with a \e{help topic} name for Windows Help, which typically appears just after the \cw{\\C} chapter title paragraph, similar to this: \c \C{net} \i{Net} \c \c \cfg{winhelp-topic}{games.net} But HTML Help is able to use the Halibut identifier for the chapter itself, i.e. the keyword that appears in braces immediatey after the \cw{\\C}. So the corresponding game back end encodes the \c{winhelp-topic} string (here \cq{games.net}) in the \c{winhelp_topic} element of the game structure, and puts the chapter identifier (here \cq{net}) in the \c{htmlhelp_topic} element. For example: \c const struct game thegame = { \c "Net", "games.net", "net", \c // ... \c }; \H{backend-params} Handling game parameter sets In this section I present the various functions which handle the \c{game_params} structure. \S{backend-default-params} \cw{default_params()} \c game_params *(*default_params)(void); This function allocates a new \c{game_params} structure, fills it with the default values, and returns a pointer to it. \S{backend-fetch-preset} \cw{fetch_preset()} \c bool (*fetch_preset)(int i, char **name, game_params **params); This function is one of the two APIs a back end can provide to populate the \q{Type} menu, which provides a list of conveniently accessible preset parameters for most games. The function is called with \c{i} equal to the index of the preset required (numbering from zero). It returns \cw{false} if that preset does not exist (if \c{i} is less than zero or greater than the largest preset index). Otherwise, it sets \c{*params} to point at a newly allocated \c{game_params} structure containing the preset information, sets \c{*name} to point at a newly allocated C string containing the preset title (to go on the \q{Type} menu), and returns \cw{true}. If the game does not wish to support any presets at all, this function is permitted to return \cw{false} always. If the game wants to return presets in the form of a hierarchical menu instead of a flat list (and, indeed, even if it doesn't), then it may set this function pointer to \cw{NULL}, and instead fill in the alternative function pointer \cw{preset_menu} (\k{backend-preset-menu}). \S{backend-preset-menu} \cw{preset_menu()} \c struct preset_menu *(*preset_menu)(void); This function is the more flexible of the two APIs by which a back end can define a collection of preset game parameters. This function simply returns a complete menu hierarchy, in the form of a \c{struct preset_menu} (see \k{midend-get-presets}) and further submenus (if it wishes) dangling off it. There are utility functions described in \k{utils-presets} to make it easy for the back end to construct this menu. If the game has no need to return a hierarchy of menus, it may instead opt to implement the \cw{fetch_preset()} function (see \k{backend-fetch-preset}). The game need not fill in the \c{id} fields in the preset menu structures. The mid-end will do that after it receives the structure from the game, and before passing it on to the front end. \S{backend-encode-params} \cw{encode_params()} \c char *(*encode_params)(const game_params *params, bool full); The job of this function is to take a \c{game_params}, and encode it in a printable ASCII string form for use in game IDs. The return value must be a newly allocated C string, and \e{must} not contain a colon or a hash (since those characters are used to mark the end of the parameter section in a game ID). Ideally, it should also not contain any other potentially controversial punctuation; bear in mind when designing a string parameter format that it will probably be used on both Windows and Unix command lines under a variety of exciting shell quoting and metacharacter rules. Sticking entirely to alphanumerics is the safest thing; if you really need punctuation, you can probably get away with commas, periods or underscores without causing anybody any major inconvenience. If you venture far beyond that, you're likely to irritate \e{somebody}. (At the time of writing this, most existing games have purely alphanumeric string parameter formats. Usually these involve a letter denoting a parameter, followed optionally by a number giving the value of that parameter, with a few mandatory parts at the beginning such as numeric width and height separated by \cq{x}.) If the \c{full} parameter is \cw{true}, this function should encode absolutely everything in the \c{game_params}, such that a subsequent call to \cw{decode_params()} (\k{backend-decode-params}) will yield an identical structure. If \c{full} is \cw{false}, however, you should leave out anything which is not necessary to describe a \e{specific puzzle instance}, i.e. anything which only takes effect when a new puzzle is \e{generated}. For example, the Solo \c{game_params} includes a difficulty rating used when constructing new puzzles; but a Solo game ID need not explicitly include the difficulty, since to describe a puzzle once generated it's sufficient to give the grid dimensions and the location and contents of the clue squares. (Indeed, one might very easily type in a puzzle out of a newspaper without \e{knowing} what its difficulty level is in Solo's terminology.) Therefore, Solo's \cw{encode_params()} only encodes the difficulty level if \c{full} is set. \S{backend-decode-params} \cw{decode_params()} \c void (*decode_params)(game_params *params, char const *string); This function is the inverse of \cw{encode_params()} (\k{backend-encode-params}). It parses the supplied string and fills in the supplied \c{game_params} structure. Note that the structure will \e{already} have been allocated: this function is not expected to create a \e{new} \c{game_params}, but to modify an existing one. This function can receive a string which only encodes a subset of the parameters. The most obvious way in which this can happen is if the string was constructed by \cw{encode_params()} with its \c{full} parameter set to \cw{false}; however, it could also happen if the user typed in a parameter set manually and missed something out. Be prepared to deal with a wide range of possibilities. When dealing with a parameter which is not specified in the input string, what to do requires a judgment call on the part of the programmer. Sometimes it makes sense to adjust other parameters to bring them into line with the new ones. In Mines, for example, you would probably not want to keep the same mine count if the user dropped the grid size and didn't specify one, since you might easily end up with more mines than would actually fit in the grid! On the other hand, sometimes it makes sense to leave the parameter alone: a Solo player might reasonably expect to be able to configure size and difficulty independently of one another. This function currently has no direct means of returning an error if the string cannot be parsed at all. However, the returned \c{game_params} is almost always subsequently passed to \cw{validate_params()} (\k{backend-validate-params}), so if you really want to signal parse errors, you could always have a \c{char *} in your parameters structure which stored an error message, and have \cw{validate_params()} return it if it is non-\cw{NULL}. \S{backend-free-params} \cw{free_params()} \c void (*free_params)(game_params *params); This function frees a \c{game_params} structure, and any subsidiary allocations contained within it. \S{backend-dup-params} \cw{dup_params()} \c game_params *(*dup_params)(const game_params *params); This function allocates a new \c{game_params} structure and initialises it with an exact copy of the information in the one provided as input. It returns a pointer to the new duplicate. \S{backend-can-configure} \c{can_configure} \c bool can_configure; This data element is set to \cw{true} if the back end supports custom parameter configuration via a dialog box. If it is \cw{true}, then the functions \cw{configure()} and \cw{custom_params()} are expected to work. See \k{backend-configure} and \k{backend-custom-params} for more details. \S{backend-configure} \cw{configure()} \c config_item *(*configure)(const game_params *params); This function is called when the user requests a dialog box for custom parameter configuration. It returns a newly allocated array of \cw{config_item} structures, describing the GUI elements required in the dialog box. The array should have one more element than the number of controls, since it is terminated with a \cw{C_END} marker (see below). Each array element describes the control together with its initial value; the front end will modify the value fields and return the updated array to \cw{custom_params()} (see \k{backend-custom-params}). The \cw{config_item} structure contains the following elements: \c char *name; \c int type; \c union { /* type-specific fields */ } u; \e iiiiiiiiiiiiiiiiiiiiiiiiii \c{name} is an ASCII string giving the textual label for a GUI control. It is \e{not} expected to be dynamically allocated. \c{type} contains one of a small number of \c{enum} values defining what type of control is being described. The usable member of the union field \c{u} depends on \c{type}. The valid type values are: \dt \c{C_STRING} \dd Describes a text input box. (This is also used for numeric input. The back end does not bother informing the front end that the box is numeric rather than textual; some front ends do have the capacity to take this into account, but I decided it wasn't worth the extra complexity in the interface.) \lcont{ For controls of this type, \c{u.string} contains a single field \c char *sval; which stores a dynamically allocated string representing the contents of the input box. } \dt \c{C_BOOLEAN} \dd Describes a simple checkbox. \lcont{ For controls of this type, \c{u.boolean} contains a single field \c bool bval; } \dt \c{C_CHOICES} \dd Describes a drop-down list presenting one of a small number of fixed choices. \lcont{ For controls of this type, \c{u.choices} contains two fields: \c const char *choicenames; \c int selected; \c{choicenames} contains a list of strings describing the choices. The very first character of \c{sval} is used as a delimiter when processing the rest (so that the strings \cq{:zero:one:two}, \cq{!zero!one!two} and \cq{xzeroxonextwo} all define a three-element list containing \cq{zero}, \cq{one} and \cq{two}). \c{selected} contains the index of the currently selected element, numbering from zero (so that in the above example, 0 would mean \cq{zero} and 2 would mean \cq{two}). Note that \c{u.choices.choicenames} is \e{not} dynamically allocated, unlike \c{u.string.sval}. } \dt \c{C_END} \dd Marks the end of the array of \c{config_item}s. There is no associated member of the union field \c{u} for this type. The array returned from this function is expected to have filled in the initial values of all the controls according to the input \c{game_params} structure. If the game's \c{can_configure} flag is set to \cw{false}, this function is never called and need not do anything at all. \S{backend-custom-params} \cw{custom_params()} \c game_params *(*custom_params)(const config_item *cfg); This function is the counterpart to \cw{configure()} (\k{backend-configure}). It receives as input an array of \c{config_item}s which was originally created by \cw{configure()}, but in which the control values have since been changed in accordance with user input. Its function is to read the new values out of the controls and return a newly allocated \c{game_params} structure representing the user's chosen parameter set. (The front end will have modified the controls' \e{values}, but there will still always be the same set of controls, in the same order, as provided by \cw{configure()}. It is not necessary to check the \c{name} and \c{type} fields, although you could use \cw{assert()} if you were feeling energetic.) This function is not expected to (and indeed \e{must not}) free the input \c{config_item} array. (If the parameters fail to validate, the dialog box will stay open.) If the game's \c{can_configure} flag is set to \cw{false}, this function is never called and need not do anything at all. \S{backend-validate-params} \cw{validate_params()} \c const char *(*validate_params)(const game_params *params, \c bool full); This function takes a \c{game_params} structure as input, and checks that the parameters described in it fall within sensible limits. (At the very least, grid dimensions should almost certainly be strictly positive, for example.) Return value is \cw{NULL} if no problems were found, or alternatively a (non-dynamically-allocated) ASCII string describing the error in human-readable form. If the \c{full} parameter is set, full validation should be performed: any set of parameters which would not permit generation of a sensible puzzle should be faulted. If \c{full} is \e{not} set, the implication is that these parameters are not going to be used for \e{generating} a puzzle; so parameters which can't even sensibly \e{describe} a valid puzzle should still be faulted, but parameters which only affect puzzle generation should not be. (The \c{full} option makes a difference when parameter combinations are non-orthogonal. For example, Net has a boolean option controlling whether it enforces a unique solution; it turns out that it's impossible to generate a uniquely soluble puzzle with wrapping walls and width 2, so \cw{validate_params()} will complain if you ask for one. However, if the user had just been playing a unique wrapping puzzle of a more sensible width, and then pastes in a game ID acquired from somebody else which happens to describe a \e{non}-unique wrapping width-2 puzzle, then \cw{validate_params()} will be passed a \c{game_params} containing the width and wrapping settings from the new game ID and the uniqueness setting from the old one. This would be faulted, if it weren't for the fact that \c{full} is not set during this call, so Net ignores the inconsistency. The resulting \c{game_params} is never subsequently used to generate a puzzle; this is a promise made by the mid-end when it asks for a non-full validation.) \H{backend-descs} Handling game descriptions In this section I present the functions that deal with a textual description of a puzzle, i.e. the part that comes after the colon in a descriptive-format game ID. \S{backend-new-desc} \cw{new_desc()} \c char *(*new_desc)(const game_params *params, random_state *rs, \c char **aux, bool interactive); This function is where all the really hard work gets done. This is the function whose job is to randomly generate a new puzzle, ensuring solubility and uniqueness as appropriate. As input it is given a \c{game_params} structure and a random state (see \k{utils-random} for the random number API). It must invent a puzzle instance, encode it in printable ASCII string form, and return a dynamically allocated C string containing that encoding. Additionally, it may return a second dynamically allocated string in \c{*aux}. (If it doesn't want to, then it can leave that parameter completely alone; it isn't required to set it to \cw{NULL}, although doing so is harmless.) That string, if present, will be passed to \cw{solve()} (\k{backend-solve}) later on; so if the puzzle is generated in such a way that a solution is known, then information about that solution can be saved in \c{*aux} for \cw{solve()} to use. The \c{interactive} parameter should be ignored by almost all puzzles. Its purpose is to distinguish between generating a puzzle within a GUI context for immediate play, and generating a puzzle in a command-line context for saving to be played later. The only puzzle that currently uses this distinction (and, I fervently hope, the only one which will \e{ever} need to use it) is Mines, which chooses a random first-click location when generating puzzles non-interactively, but which waits for the user to place the first click when interactive. If you think you have come up with another puzzle which needs to make use of this parameter, please think for at least ten minutes about whether there is \e{any} alternative! Note that game description strings are not required to contain an encoding of parameters such as grid size; a game description is never separated from the \c{game_params} it was generated with, so any information contained in that structure need not be encoded again in the game description. \S{backend-validate-desc} \cw{validate_desc()} \c const char *(*validate_desc)(const game_params *params, \c const char *desc); This function is given a game description, and its job is to validate that it describes a puzzle which makes sense. To some extent it's up to the user exactly how far they take the phrase \q{makes sense}; there are no particularly strict rules about how hard the user is permitted to shoot themself in the foot when typing in a bogus game description by hand. (For example, Rectangles will not verify that the sum of all the numbers in the grid equals the grid's area. So a user could enter a puzzle which was provably not soluble, and the program wouldn't complain; there just wouldn't happen to be any sequence of moves which solved it.) The one non-negotiable criterion is that any game description which makes it through \cw{validate_desc()} \e{must not} subsequently cause a crash or an assertion failure when fed to \cw{new_game()} and thence to the rest of the back end. The return value is \cw{NULL} on success, or a non-dynamically-allocated C string containing an error message. \S{backend-new-game} \cw{new_game()} \c game_state *(*new_game)(midend *me, const game_params *params, \c const char *desc); This function takes a game description as input, together with its accompanying \c{game_params}, and constructs a \c{game_state} describing the initial state of the puzzle. It returns a newly allocated \c{game_state} structure. Almost all puzzles should ignore the \c{me} parameter. It is required by Mines, which needs it for later passing to \cw{midend_supersede_game_desc()} (see \k{backend-supersede}) once the user has placed the first click. I fervently hope that no other puzzle will be awkward enough to require it, so everybody else should ignore it. As with the \c{interactive} parameter in \cw{new_desc()} (\k{backend-new-desc}), if you think you have a reason to need this parameter, please try very hard to think of an alternative approach! \H{backend-states} Handling game states This section describes the functions which create and destroy \c{game_state} structures. (Well, except \cw{new_game()}, which is in \k{backend-new-game} instead of under here; but it deals with game descriptions \e{and} game states and it had to go in one section or the other.) \S{backend-dup-game} \cw{dup_game()} \c game_state *(*dup_game)(const game_state *state); This function allocates a new \c{game_state} structure and initialises it with an exact copy of the information in the one provided as input. It returns a pointer to the new duplicate. \S{backend-free-game} \cw{free_game()} \c void (*free_game)(game_state *state); This function frees a \c{game_state} structure, and any subsidiary allocations contained within it. \H{backend-ui} Handling \c{game_ui} \S{backend-new-ui} \cw{new_ui()} \c game_ui *(*new_ui)(const game_state *state); This function allocates and returns a new \c{game_ui} structure for playing a particular puzzle. It is passed a pointer to the initial \c{game_state}, in case it needs to refer to that when setting up the initial values for the new game. \S{backend-free-ui} \cw{free_ui()} \c void (*free_ui)(game_ui *ui); This function frees a \c{game_ui} structure, and any subsidiary allocations contained within it. \S{backend-encode-ui} \cw{encode_ui()} \c char *(*encode_ui)(const game_ui *ui); This function encodes any \e{important} data in a \c{game_ui} structure in printable ASCII string form. It is only called when saving a half-finished game to a file. It should be used sparingly. Almost all data in a \c{game_ui} is not important enough to save. The location of the keyboard-controlled cursor, for example, can be reset to a default position on reloading the game without impacting the user experience. If the user should somehow manage to save a game while a mouse drag was in progress, then discarding that mouse drag would be an outright \e{feature}. A typical thing that \e{would} be worth encoding in this function is the Mines death counter: it's in the \c{game_ui} rather than the \c{game_state} because it's too important to allow the user to revert it by using Undo, and therefore it's also too important to allow the user to revert it by saving and reloading. (Of course, the user could edit the save file by hand... But if the user is \e{that} determined to cheat, they could just as easily modify the game's source.) \S{backend-decode-ui} \cw{decode_ui()} \c void (*decode_ui)(game_ui *ui, const char *encoding); This function parses a string previously output by \cw{encode_ui()}, and writes the decoded data back into the freshly-created \c{game_ui} structure provided. If the string is invalid, the function should do the best it can, which might just mean not changing the \c{game_ui} structure at all. This might happen if a save file is corrupted, or simply from a newer version that encodes more \c{game_ui} data. \S{backend-changed-state} \cw{changed_state()} \c void (*changed_state)(game_ui *ui, const game_state *oldstate, \c const game_state *newstate); This function is called by the mid-end whenever the current game state changes, for any reason. Those reasons include: \b a fresh move being made by \cw{interpret_move()} and \cw{execute_move()} \b a solve operation being performed by \cw{solve()} and \cw{execute_move()} \b the user moving back and forth along the undo list by means of the Undo and Redo operations \b the user selecting Restart to go back to the initial game state. The job of \cw{changed_state()} is to update the \c{game_ui} for consistency with the new game state, if any update is necessary. For example, Same Game stores data about the currently selected tile group in its \c{game_ui}, and this data is intrinsically related to the game state it was derived from. So it's very likely to become invalid when the game state changes; thus, Same Game's \cw{changed_state()} function clears the current selection whenever it is called. When \cw{anim_length()} or \cw{flash_length()} are called, you can be sure that there has been a previous call to \cw{changed_state()}. So \cw{changed_state()} can set up data in the \c{game_ui} which will be read by \cw{anim_length()} and \cw{flash_length()}, and those functions will not have to worry about being called without the data having been initialised. \H{backend-moves} Making moves This section describes the functions which actually make moves in the game: that is, the functions which process user input and end up producing new \c{game_state}s. \S{backend-interpret-move} \cw{interpret_move()} \c char *(*interpret_move)(const game_state *state, game_ui *ui, \c const game_drawstate *ds, \c int x, int y, int button); This function receives user input and processes it. Its input parameters are the current \c{game_state}, the current \c{game_ui} and the current \c{game_drawstate}, plus details of the input event. \c{button} is either an ASCII value or a special code (listed below) indicating an arrow or function key or a mouse event; when \c{button} is a mouse event, \c{x} and \c{y} contain the pixel coordinates of the mouse pointer relative to the top left of the puzzle's drawing area. (The pointer to the \c{game_drawstate} is marked \c{const}, because \c{interpret_move} should not write to it. The normal use of that pointer will be to read the game's tile size parameter in order to divide mouse coordinates by it.) \cw{interpret_move()} may return in three different ways: \b Returning \cw{NULL} indicates that no action whatsoever occurred in response to the input event; the puzzle was not interested in it at all. \b Returning the special value \cw{UI_UPDATE} indicates that the input event has resulted in a change being made to the \c{game_ui} which will require a redraw of the game window, but that no actual \e{move} was made (i.e. no new \c{game_state} needs to be created). \b Returning anything else indicates that a move was made and that a new \c{game_state} must be created. However, instead of actually constructing a new \c{game_state} itself, this function is required to return a printable ASCII string description of the details of the move. This string will be passed to \cw{execute_move()} (\k{backend-execute-move}) to actually create the new \c{game_state}. (Encoding moves as strings in this way means that the mid-end can keep the strings as well as the game states, and the strings can be written to disk when saving the game and fed to \cw{execute_move()} again on reloading.) The return value from \cw{interpret_move()} is expected to be dynamically allocated if and only if it is not either \cw{NULL} \e{or} the special string constant \c{UI_UPDATE}. After this function is called, the back end is permitted to rely on some subsequent operations happening in sequence: \b \cw{execute_move()} will be called to convert this move description into a new \c{game_state} \b \cw{changed_state()} will be called with the new \c{game_state}. This means that if \cw{interpret_move()} needs to do updates to the \c{game_ui} which are easier to perform by referring to the new \c{game_state}, it can safely leave them to be done in \cw{changed_state()} and not worry about them failing to happen. (Note, however, that \cw{execute_move()} may \e{also} be called in other circumstances. It is only \cw{interpret_move()} which can rely on a subsequent call to \cw{changed_state()}.) The special key codes supported by this function are: \dt \cw{LEFT_BUTTON}, \cw{MIDDLE_BUTTON}, \cw{RIGHT_BUTTON} \dd Indicate that one of the mouse buttons was pressed down. \dt \cw{LEFT_DRAG}, \cw{MIDDLE_DRAG}, \cw{RIGHT_DRAG} \dd Indicate that the mouse was moved while one of the mouse buttons was still down. The mid-end guarantees that when one of these events is received, it will always have been preceded by a button-down event (and possibly other drag events) for the same mouse button, and no event involving another mouse button will have appeared in between. \dt \cw{LEFT_RELEASE}, \cw{MIDDLE_RELEASE}, \cw{RIGHT_RELEASE} \dd Indicate that a mouse button was released. The mid-end guarantees that when one of these events is received, it will always have been preceded by a button-down event (and possibly some drag events) for the same mouse button, and no event involving another mouse button will have appeared in between. \dt \cw{CURSOR_UP}, \cw{CURSOR_DOWN}, \cw{CURSOR_LEFT}, \cw{CURSOR_RIGHT} \dd Indicate that an arrow key was pressed. \dt \cw{CURSOR_SELECT}, \cw{CURSOR_SELECT2} \dd On platforms which have one or two prominent \q{select} button alongside their cursor keys, indicates that one of those buttons was pressed. On other platforms, these represent the Enter (or Return) and Space keys respectively. In addition, there are some modifiers which can be bitwise-ORed into the \c{button} parameter: \dt \cw{MOD_CTRL}, \cw{MOD_SHFT} \dd These indicate that the Control or Shift key was pressed alongside the key. They only apply to the cursor keys, not to mouse buttons or anything else. \dt \cw{MOD_NUM_KEYPAD} \dd This applies to some ASCII values, and indicates that the key code was input via the numeric keypad rather than the main keyboard. Some puzzles may wish to treat this differently (for example, a puzzle might want to use the numeric keypad as an eight-way directional pad), whereas others might not (a game involving numeric input probably just wants to treat the numeric keypad as numbers). \dt \cw{MOD_MASK} \dd This mask is the bitwise OR of all the available modifiers; you can bitwise-AND with \cw{~MOD_MASK} to strip all the modifiers off any input value. \S{backend-execute-move} \cw{execute_move()} \c game_state *(*execute_move)(const game_state *state, char *move); This function takes an input \c{game_state} and a move string as output from \cw{interpret_move()}. It returns a newly allocated \c{game_state} which contains the result of applying the specified move to the input game state. This function may return \cw{NULL} if it cannot parse the move string (and this is definitely preferable to crashing or failing an assertion, since one way this can happen is if loading a corrupt save file). However, it must not return \cw{NULL} for any move string that really was output from \cw{interpret_move()}: this is punishable by assertion failure in the mid-end. \S{backend-can-solve} \c{can_solve} \c bool can_solve; This field is set to \cw{true} if the game's \cw{solve()} function does something. If it's set to \cw{false}, the game will not even offer the \q{Solve} menu option. \S{backend-solve} \cw{solve()} \c char *(*solve)(const game_state *orig, const game_state *curr, \c const char *aux, const char **error); This function is called when the user selects the \q{Solve} option from the menu. It is passed two input game states: \c{orig} is the game state from the very start of the puzzle, and \c{curr} is the current one. (Different games find one or other or both of these convenient.) It is also passed the \c{aux} string saved by \cw{new_desc()} (\k{backend-new-desc}), in case that encodes important information needed to provide the solution. If this function is unable to produce a solution (perhaps, for example, the game has no in-built solver so it can only solve puzzles it invented internally and has an \c{aux} string for) then it may return \cw{NULL}. If it does this, it must also set \c{*error} to an error message to be presented to the user (such as \q{Solution not known for this puzzle}); that error message is not expected to be dynamically allocated. If this function \e{does} produce a solution, it returns a printable ASCII move string suitable for feeding to \cw{execute_move()} (\k{backend-execute-move}). Like a (non-empty) string returned from \cw{interpret_move()}, the returned string should be dynamically allocated. \H{backend-drawing} Drawing the game graphics This section discusses the back end functions that deal with drawing. \S{backend-new-drawstate} \cw{new_drawstate()} \c game_drawstate *(*new_drawstate)(drawing *dr, \c const game_state *state); This function allocates and returns a new \c{game_drawstate} structure for drawing a particular puzzle. It is passed a pointer to a \c{game_state}, in case it needs to refer to that when setting up any initial data. This function may not rely on the puzzle having been newly started; a new draw state can be constructed at any time if the front end requests a forced redraw. For games like Pattern, in which initial game states are much simpler than general ones, this might be important to keep in mind. The parameter \c{dr} is a drawing object (see \k{drawing}) which the function might need to use to allocate blitters. (However, this isn't recommended; it's usually more sensible to wait to allocate a blitter until \cw{set_size()} is called, because that way you can tailor it to the scale at which the puzzle is being drawn.) \S{backend-free-drawstate} \cw{free_drawstate()} \c void (*free_drawstate)(drawing *dr, game_drawstate *ds); This function frees a \c{game_drawstate} structure, and any subsidiary allocations contained within it. The parameter \c{dr} is a drawing object (see \k{drawing}), which might be required if you are freeing a blitter. \S{backend-preferred-tilesize} \c{preferred_tilesize} \c int preferred_tilesize; Each game is required to define a single integer parameter which expresses, in some sense, the scale at which it is drawn. This is described in the APIs as \cq{tilesize}, since most puzzles are on a square (or possibly triangular or hexagonal) grid and hence a sensible interpretation of this parameter is to define it as the size of one grid tile in pixels; however, there's no actual requirement that the \q{tile size} be proportional to the game window size. Window size is required to increase monotonically with \q{tile size}, however. The data element \c{preferred_tilesize} indicates the tile size which should be used in the absence of a good reason to do otherwise (such as the screen being too small to fit the whole puzzle, or the user explicitly requesting a resize). \S{backend-compute-size} \cw{compute_size()} \c void (*compute_size)(const game_params *params, int tilesize, \c int *x, int *y); This function is passed a \c{game_params} structure and a tile size. It returns, in \c{*x} and \c{*y}, the size in pixels of the drawing area that would be required to render a puzzle with those parameters at that tile size. \S{backend-set-size} \cw{set_size()} \c void (*set_size)(drawing *dr, game_drawstate *ds, \c const game_params *params, int tilesize); This function is responsible for setting up a \c{game_drawstate} to draw at a given tile size. Typically this will simply involve copying the supplied \c{tilesize} parameter into a \c{tilesize} field inside the draw state; for some more complex games it might also involve setting up other dimension fields, or possibly allocating a blitter (see \k{drawing-blitter}). The parameter \c{dr} is a drawing object (see \k{drawing}), which is required if a blitter needs to be allocated. Back ends may assume (and may enforce by assertion) that this function will be called at most once for any \c{game_drawstate}. If a puzzle needs to be redrawn at a different size, the mid-end will create a fresh drawstate. \S{backend-colours} \cw{colours()} \c float *(*colours)(frontend *fe, int *ncolours); This function is responsible for telling the front end what colours the puzzle will need to draw itself. It returns the number of colours required in \c{*ncolours}, and the return value from the function itself is a dynamically allocated array of three times that many \c{float}s, containing the red, green and blue components of each colour respectively as numbers in the range [0,1]. The second parameter passed to this function is a front end handle. The only things it is permitted to do with this handle are to call the front-end function called \cw{frontend_default_colour()} (see \k{frontend-default-colour}) or the utility function called \cw{game_mkhighlight()} (see \k{utils-game-mkhighlight}). (The latter is a wrapper on the former, so front end implementors only need to provide \cw{frontend_default_colour()}.) This allows \cw{colours()} to take local configuration into account when deciding on its own colour allocations. Most games use the front end's default colour as their background, apart from a few which depend on drawing relief highlights so they adjust the background colour if it's too light for highlights to show up against it. The first colour in the list is slightly special. The mid-end fills the drawing area with it before the first call to \cw{redraw()} (see \k{backend-redraw}). Some front ends also use it fill the part of the puzzle window outside the puzzle. This means that it is usually sensible to make colour 0 the background colour for the puzzle. Note that the colours returned from this function are for \e{drawing}, not for printing. Printing has an entirely different colour allocation policy. \S{backend-anim-length} \cw{anim_length()} \c float (*anim_length)(const game_state *oldstate, \c const game_state *newstate, \c int dir, game_ui *ui); This function is called when a move is made, undone or redone. It is given the old and the new \c{game_state}, and its job is to decide whether the transition between the two needs to be animated or can be instant. \c{oldstate} is the state that was current until this call; \c{newstate} is the state that will be current after it. \c{dir} specifies the chronological order of those states: if it is positive, then the transition is the result of a move or a redo (and so \c{newstate} is the later of the two moves), whereas if it is negative then the transition is the result of an undo (so that \c{newstate} is the \e{earlier} move). If this function decides the transition should be animated, it returns the desired length of the animation in seconds. If not, it returns zero. State changes as a result of a Restart operation are never animated; the mid-end will handle them internally and never consult this function at all. State changes as a result of Solve operations are also not animated by default, although you can change this for a particular game by setting a flag in \c{flags} (\k{backend-flags}). The function is also passed a pointer to the local \c{game_ui}. It may refer to information in here to help with its decision (see \k{writing-conditional-anim} for an example of this), and/or it may \e{write} information about the nature of the animation which will be read later by \cw{redraw()}. When this function is called, it may rely on \cw{changed_state()} having been called previously, so if \cw{anim_length()} needs to refer to information in the \c{game_ui}, then \cw{changed_state()} is a reliable place to have set that information up. Move animations do not inhibit further input events. If the user continues playing before a move animation is complete, the animation will be abandoned and the display will jump straight to the final state. \S{backend-flash-length} \cw{flash_length()} \c float (*flash_length)(const game_state *oldstate, \c const game_state *newstate, \c int dir, game_ui *ui); This function is called when a move is completed. (\q{Completed} means that not only has the move been made, but any animation which accompanied it has finished.) It decides whether the transition from \c{oldstate} to \c{newstate} merits a \q{flash}. A flash is much like a move animation, but it is \e{not} interrupted by further user interface activity; it runs to completion in parallel with whatever else might be going on on the display. The only thing which will rush a flash to completion is another flash. The purpose of flashes is to indicate that the game has been completed. They were introduced as a separate concept from move animations because of Net: the habit of most Net players (and certainly me) is to rotate a tile into place and immediately lock it, then move on to another tile. When you make your last move, at the instant the final tile is rotated into place the screen starts to flash to indicate victory \dash but if you then press the lock button out of habit, then the move animation is cancelled, and the victory flash does not complete. (And if you \e{don't} press the lock button, the completed grid will look untidy because there will be one unlocked square.) Therefore, I introduced a specific concept of a \q{flash} which is separate from a move animation and can proceed in parallel with move animations and any other display activity, so that the victory flash in Net is not cancelled by that final locking move. The input parameters to \cw{flash_length()} are exactly the same as the ones to \cw{anim_length()}: see \k{backend-anim-length}. Just like \cw{anim_length()}, when this function is called, it may rely on \cw{changed_state()} having been called previously, so if it needs to refer to information in the \c{game_ui} then \cw{changed_state()} is a reliable place to have set that information up. (Some games use flashes to indicate defeat as well as victory; Mines, for example, flashes in a different colour when you tread on a mine from the colour it uses when you complete the game. In order to achieve this, its \cw{flash_length()} function has to store a flag in the \c{game_ui} to indicate which flash type is required.) \S{backend-get-cursor-location} \cw{get_cursor_location()} \c void (*get_cursor_location)(const game_ui *ui, \c const game_drawstate *ds, \c const game_state *state, \c const game_params *params, \c int *x, int *y, \c int *w, int *h); This function queries the backend for the rectangular region containing the cursor (in games that have one), or other region of interest. This function is called by only \cw{midend_get_cursor_location()} (\k{midend-get-cursor-location}). Its purpose is to allow front ends to query the location of the backend's cursor. With knowledge of this location, a front end can, for example, ensure that the region of interest remains visible if the puzzle is too big to fit on the screen at once. On returning, \cw{*x}, \cw{*y} should be set to the X and Y coordinates of the upper-left corner of the rectangular region of interest, and \cw{*w} and \cw{*h} should be the width and height of that region, respectively. In the event that a cursor is not visible on screen, this function should return and leave the return parameters untouched \dash the midend will notice this. The backend need not bother checking that \cw{x}, \cw{y}, \cw{w} and \cw{h} are non-\cw{NULL} \dash the midend guarantees that they will not be. Defining what constitutes a \q{region of interest} is left up to the backend. If a game provides a conventional cursor \dash such as Mines, Solo, or any of the other grid-based games \dash the most logical choice is of course the location of the cursor itself. However, in other cases such as Cube or Inertia, there is no \q{cursor} in the conventional sense \dash the player instead controls an object moving around the screen. In these cases, it makes sense to define the region of interest as the bounding box of the player object or another sensible region \dash such as the grid square the player is sitting on in Cube. If a backend does not provide a cursor mechanism at all, the backend is free to provide an empty implementation of this function, or a \cw{NULL} pointer in the \cw{game} structure \dash the midend will notice either of these cases and behave appropriately. \S{backend-status} \cw{status()} \c int (*status)(const game_state *state); This function returns a status value indicating whether the current game is still in play, or has been won, or has been conclusively lost. The mid-end uses this to implement \cw{midend_status()} (\k{midend-status}). The return value should be +1 if the game has been successfully solved. If the game has been lost in a situation where further play is unlikely, the return value should be -1. If neither is true (so play is still ongoing), return zero. Front ends may wish to use a non-zero status as a cue to proactively offer the option of starting a new game. Therefore, back ends should not return -1 if the game has been \e{technically} lost but undoing and continuing is still a realistic possibility. (For instance, games with hidden information such as Guess or Mines might well return a non-zero status whenever they reveal the solution, whether or not the player guessed it correctly, on the grounds that a player would be unlikely to hide the solution and continue playing after the answer was spoiled. On the other hand, games where you can merely get into a dead end such as Same Game or Inertia might choose to return 0 in that situation, on the grounds that the player would quite likely press Undo and carry on playing.) \S{backend-redraw} \cw{redraw()} \c void (*redraw)(drawing *dr, game_drawstate *ds, \c const game_state *oldstate, \c const game_state *newstate, \c int dir, const game_ui *ui, \c float anim_time, float flash_time); This function is responsible for actually drawing the contents of the game window, and for redrawing every time the game state or the \c{game_ui} changes. The parameter \c{dr} is a drawing object which may be passed to the drawing API functions (see \k{drawing} for documentation of the drawing API). This function may not save \c{dr} and use it elsewhere; it must only use it for calling back to the drawing API functions within its own lifetime. \c{ds} is the local \c{game_drawstate}, of course, and \c{ui} is the local \c{game_ui}. \c{newstate} is the semantically-current game state, and is always non-\cw{NULL}. If \c{oldstate} is also non-\cw{NULL}, it means that a move has recently been made and the game is still in the process of displaying an animation linking the old and new states; in this situation, \c{anim_time} will give the length of time (in seconds) that the animation has already been running. If \c{oldstate} is \cw{NULL}, then \c{anim_time} is unused (and will hopefully be set to zero to avoid confusion). \c{dir} specifies the chronological order of those states: if it is positive, then the transition is the result of a move or a redo (and so \c{newstate} is the later of the two moves), whereas if it is negative then the transition is the result of an undo (so that \c{newstate} is the \e{earlier} move). This allows move animations that are not time-symmetric (such as Inertia, where gems are consumed during the animation) to be drawn the right way round. \c{flash_time}, if it is is non-zero, denotes that the game is in the middle of a flash, and gives the time since the start of the flash. See \k{backend-flash-length} for general discussion of flashes. The very first time this function is called for a new \c{game_drawstate}, it is expected to redraw the \e{entire} drawing area. Since this often involves drawing visual furniture which is never subsequently altered, it is often simplest to arrange this by having a special \q{first time} flag in the draw state, and resetting it after the first redraw. This function can assume that the mid-end has filled the drawing area with colour 0 before the first call. When this function (or any subfunction) calls the drawing API, it is expected to pass colour indices which were previously defined by the \cw{colours()} function. \H{backend-printing} Printing functions This section discusses the back end functions that deal with printing puzzles out on paper. \S{backend-can-print} \c{can_print} \c bool can_print; This flag is set to \cw{true} if the puzzle is capable of printing itself on paper. (This makes sense for some puzzles, such as Solo, which can be filled in with a pencil. Other puzzles, such as Twiddle, inherently involve moving things around and so would not make sense to print.) If this flag is \cw{false}, then the functions \cw{print_size()} and \cw{print()} will never be called. \S{backend-can-print-in-colour} \c{can_print_in_colour} \c bool can_print_in_colour; This flag is set to \cw{true} if the puzzle is capable of printing itself differently when colour is available. For example, Map can actually print coloured regions in different \e{colours} rather than resorting to cross-hatching. If the \c{can_print} flag is \cw{false}, then this flag will be ignored. \S{backend-print-size} \cw{print_size()} \c void (*print_size)(const game_params *params, float *x, float *y); This function is passed a \c{game_params} structure and a tile size. It returns, in \c{*x} and \c{*y}, the preferred size in \e{millimetres} of that puzzle if it were to be printed out on paper. If the \c{can_print} flag is \cw{false}, this function will never be called. \S{backend-print} \cw{print()} \c void (*print)(drawing *dr, const game_state *state, int tilesize); This function is called when a puzzle is to be printed out on paper. It should use the drawing API functions (see \k{drawing}) to print itself. This function is separate from \cw{redraw()} because it is often very different: \b The printing function may not depend on pixel accuracy, since printer resolution is variable. Draw as if your canvas had infinite resolution. \b The printing function sometimes needs to display things in a completely different style. Net, for example, is very different as an on-screen puzzle and as a printed one. \b The printing function is often much simpler since it has no need to deal with repeated partial redraws. However, there's no reason the printing and redraw functions can't share some code if they want to. When this function (or any subfunction) calls the drawing API, the colour indices it passes should be colours which have been allocated by the \cw{print_*_colour()} functions within this execution of \cw{print()}. This is very different from the fixed small number of colours used in \cw{redraw()}, because printers do not have a limitation on the total number of colours that may be used. Some puzzles' printing functions might wish to allocate only one \q{ink} colour and use it for all drawing; others might wish to allocate \e{more} colours than are used on screen. One possible colour policy worth mentioning specifically is that a puzzle's printing function might want to allocate the \e{same} colour indices as are used by the redraw function, so that code shared between drawing and printing does not have to keep switching its colour indices. In order to do this, the simplest thing is to make use of the fact that colour indices returned from \cw{print_*_colour()} are guaranteed to be in increasing order from zero. So if you have declared an \c{enum} defining three colours \cw{COL_BACKGROUND}, \cw{COL_THIS} and \cw{COL_THAT}, you might then write \c int c; \c c = print_mono_colour(dr, 1); assert(c == COL_BACKGROUND); \c c = print_mono_colour(dr, 0); assert(c == COL_THIS); \c c = print_mono_colour(dr, 0); assert(c == COL_THAT); If the \c{can_print} flag is \cw{false}, this function will never be called. \H{backend-misc} Miscellaneous \S{backend-can-format-as-text-ever} \c{can_format_as_text_ever} \c bool can_format_as_text_ever; This field is \cw{true} if the game supports formatting a game state as ASCII text (typically ASCII art) for copying to the clipboard and pasting into other applications. If it is \cw{false}, front ends will not offer the \q{Copy} command at all. If this field is \cw{true}, the game does not necessarily have to support text formatting for \e{all} games: e.g. a game which can be played on a square grid or a triangular one might only support copy and paste for the former, because triangular grids in ASCII art are just too difficult. If this field is \cw{false}, the functions \cw{can_format_as_text_now()} (\k{backend-can-format-as-text-now}) and \cw{text_format()} (\k{backend-text-format}) are never called. \S{backend-can-format-as-text-now} \c{can_format_as_text_now()} \c bool (*can_format_as_text_now)(const game_params *params); This function is passed a \c{game_params}, and returns \cw{true} if the game can support ASCII text output for this particular game type. If it returns \cw{false}, front ends will grey out or otherwise disable the \q{Copy} command. Games may enable and disable the copy-and-paste function for different game \e{parameters}, but are currently constrained to return the same answer from this function for all game \e{states} sharing the same parameters. In other words, the \q{Copy} function may enable or disable itself when the player changes game preset, but will never change during play of a single game or when another game of exactly the same type is generated. This function should not take into account aspects of the game parameters which are not encoded by \cw{encode_params()} (\k{backend-encode-params}) when the \c{full} parameter is set to \cw{false}. Such parameters will not necessarily match up between a call to this function and a subsequent call to \cw{text_format()} itself. (For instance, game \e{difficulty} should not affect whether the game can be copied to the clipboard. Only the actual visible \e{shape} of the game can affect that.) \S{backend-text-format} \cw{text_format()} \c char *(*text_format)(const game_state *state); This function is passed a \c{game_state}, and returns a newly allocated C string containing an ASCII representation of that game state. It is used to implement the \q{Copy} operation in many front ends. This function will only ever be called if the back end field \c{can_format_as_text_ever} (\k{backend-can-format-as-text-ever}) is \cw{true} \e{and} the function \cw{can_format_as_text_now()} (\k{backend-can-format-as-text-now}) has returned \cw{true} for the currently selected game parameters. The returned string may contain line endings (and will probably want to), using the normal C internal \cq{\\n} convention. For consistency between puzzles, all multi-line textual puzzle representations should \e{end} with a newline as well as containing them internally. (There are currently no puzzles which have a one-line ASCII representation, so there's no precedent yet for whether that should come with a newline or not.) \S{backend-wants-statusbar} \cw{wants_statusbar} \c bool wants_statusbar; This field is set to \cw{true} if the puzzle has a use for a textual status line (to display score, completion status, currently active tiles, etc). If the \c{redraw()} function ever intends to call \c{status_bar()} in the drawing API (\k{drawing-status-bar}), then it should set this flag to \c{true}. \S{backend-is-timed} \c{is_timed} \c bool is_timed; This field is \cw{true} if the puzzle is time-critical. If so, the mid-end will maintain a game timer while the user plays. If this field is \cw{false}, then \cw{timing_state()} will never be called and need not do anything. \S{backend-timing-state} \cw{timing_state()} \c bool (*timing_state)(const game_state *state, game_ui *ui); This function is passed the current \c{game_state} and the local \c{game_ui}; it returns \cw{true} if the game timer should currently be running. A typical use for the \c{game_ui} in this function is to note when the game was first completed (by setting a flag in \cw{changed_state()} \dash see \k{backend-changed-state}), and freeze the timer thereafter so that the user can undo back through their solution process without altering their time. \S{backend-request-keys} \cw{request_keys()} \c key_label *(*request_keys)(const game_params *params, int *nkeys); This function returns a dynamically allocated array of \cw{key_label} items containing the buttons the back end deems absolutely \e{necessary} for gameplay, not an exhaustive list of every button the back end could accept. For example, Keen only returns the digits up to the game size and the backspace character, \cw{\\b}, even though it \e{could} accept \cw{M}, as only these buttons are actually needed to play the game. Each \cw{key_label} item contains the following fields: \c struct key_label { \c char *label; /* label for frontend use */ \c int button; /* button to pass to midend */ \c } key_label; The \cw{label} field of this structure can (and often will) be set by the backend to \cw{NULL}, in which case the midend will instead call \c{button2label()} (\k{utils-button2label}) and fill in a generic label. The \cw{button} field is the associated code that can be passed to the midend when the frontend deems appropriate. If \cw{label} is not \cw{NULL}, then it's a dynamically allocated string. Therefore, freeing an array of these structures needs more than just a single free operatio. The function \c{free_keys()} (\k{utils-free-keys}) can be used to free a whole array of these structures conveniently. The backend should set \cw{*nkeys} to the number of elements in the returned array. The field for this function point in the \cw{game} structure might be set to \cw{NULL} (and indeed it is for the majority of the games) to indicate that no additional buttons (apart from the cursor keys) are required to play the game. This function should not be called directly by frontends. Instead, frontends should use \cw{midend_request_keys()} (\k{midend-request-keys}). \S{backend-current-key-label} \cw{current_key_label()} \c const char *(*current_key_label)(const game_ui *ui, \c const game_state *state, int button); This function is called to ask the back-end how certain keys should be labelled on platforms (such a feature phones) where this is conventional. These labels are expected to reflect what the keys will do right now, so they can change depending on the game and UI state. The \c{ui} and \c{state} arguments describe the state of the game for which key labels are required. The \c{button} argument is the same as the one passed to \cw{interpret_move()}. At present, the only values of \c{button} that can be passed to \cw{current_key_label()} are \cw{CURSOR_SELECT} and \cw{CURSOR_SELECT2}. The return value is a short string describing what the requested key will do if pressed. Usually the string should be a static string constant. If it's really necessary to use a dynamically-allocated string, it should remain valid until the next call to \cw{current_key_label()} or \cw{free_ui()} with the same \cw{game_ui} (so it can be referenced from the \cw{game_ui} and freed at the next one of those calls). There's no fixed upper limit on the length of string that this function can return, but more than about 12 characters is likely to cause problems for front-ends. If two buttons have the same effect, their labels should be identical so that the front end can detect this. Similarly, keys that do different things should have different labels. The label should be an empty string (\cw{""}) if the key does nothing. Like \cw{request_keys()}, the \cw{current_key_label} pointer in the \c{game} structure is allowed to be \cw{NULL}, in which case the mid-end will treat it as though it always returned \cw{""}. \S{backend-flags} \c{flags} \c int flags; This field contains miscellaneous per-backend flags. It consists of the bitwise OR of some combination of the following: \dt \cw{BUTTON_BEATS(x,y)} \dd Given any \cw{x} and \cw{y} from the set \{\cw{LEFT_BUTTON}, \cw{MIDDLE_BUTTON}, \cw{RIGHT_BUTTON}\}, this macro evaluates to a bit flag which indicates that when buttons \cw{x} and \cw{y} are both pressed simultaneously, the mid-end should consider \cw{x} to have priority. (In the absence of any such flags, the mid-end will always consider the most recently pressed button to have priority.) \dt \cw{SOLVE_ANIMATES} \dd This flag indicates that moves generated by \cw{solve()} (\k{backend-solve}) are candidates for animation just like any other move. For most games, solve moves should not be animated, so the mid-end doesn't even bother calling \cw{anim_length()} (\k{backend-anim-length}), thus saving some special-case code in each game. On the rare occasion that animated solve moves are actually required, you can set this flag. \dt \cw{REQUIRE_RBUTTON} \dd This flag indicates that the puzzle cannot be usefully played without the use of mouse buttons other than the left one. On some PDA platforms, this flag is used by the front end to enable right-button emulation through an appropriate gesture. Note that a puzzle is not required to set this just because it \e{uses} the right button, but only if its use of the right button is critical to playing the game. (Slant, for example, uses the right button to cycle through the three square states in the opposite order from the left button, and hence can manage fine without it.) \dt \cw{REQUIRE_NUMPAD} \dd This flag indicates that the puzzle cannot be usefully played without the use of number-key input. On some PDA platforms it causes an emulated number pad to appear on the screen. Similarly to \cw{REQUIRE_RBUTTON}, a puzzle need not specify this simply if its use of the number keys is not critical. \H{backend-initiative} Things a back end may do on its own initiative This section describes a couple of things that a back end may choose to do by calling functions elsewhere in the program, which would not otherwise be obvious. \S{backend-newrs} Create a random state If a back end needs random numbers at some point during normal play, it can create a fresh \c{random_state} by first calling \c{get_random_seed} (\k{frontend-get-random-seed}) and then passing the returned seed data to \cw{random_new()}. This is likely not to be what you want. If a puzzle needs randomness in the middle of play, it's likely to be more sensible to store some sort of random state within the \c{game_state}, so that the random numbers are tied to the particular game state and hence the player can't simply keep undoing their move until they get numbers they like better. This facility is currently used only in Net, to implement the \q{jumble} command, which sets every unlocked tile to a new random orientation. This randomness \e{is} a reasonable use of the feature, because it's non-adversarial \dash there's no advantage to the user in getting different random numbers. \S{backend-supersede} Supersede its own game description In response to a move, a back end is (reluctantly) permitted to call \cw{midend_supersede_game_desc()}: \c void midend_supersede_game_desc(midend *me, \c char *desc, char *privdesc); When the user selects \q{New Game}, the mid-end calls \cw{new_desc()} (\k{backend-new-desc}) to get a new game description, and (as well as using that to generate an initial game state) stores it for the save file and for telling to the user. The function above overwrites that game description, and also splits it in two. \c{desc} becomes the new game description which is provided to the user on request, and is also the one used to construct a new initial game state if the user selects \q{Restart}. \c{privdesc} is a \q{private} game description, used to reconstruct the game's initial state when reloading. The distinction between the two, as well as the need for this function at all, comes from Mines. Mines begins with a blank grid and no idea of where the mines actually are; \cw{new_desc()} does almost no work in interactive mode, and simply returns a string encoding the \c{random_state}. When the user first clicks to open a tile, \e{then} Mines generates the mine positions, in such a way that the game is soluble from that starting point. Then it uses this function to supersede the random-state game description with a proper one. But it needs two: one containing the initial click location (because that's what you want to happen if you restart the game, and also what you want to send to a friend so that they play \e{the same game} as you), and one without the initial click location (because when you save and reload the game, you expect to see the same blank initial state as you had before saving). I should stress again that this function is a horrid hack. Nobody should use it if they're not Mines; if you think you need to use it, think again repeatedly in the hope of finding a better way to do whatever it was you needed to do. \C{drawing} The drawing API The back end function \cw{redraw()} (\k{backend-redraw}) is required to draw the puzzle's graphics on the window's drawing area. The back end function \cw{print()} similarly draws the puzzle on paper, if the puzzle is printable. To do this portably, the back end is provided with a drawing API allowing it to talk directly to the front end. In this chapter I document that API, both for the benefit of back end authors trying to use it and for front end authors trying to implement it. The drawing API as seen by the back end is a collection of global functions, each of which takes a pointer to a \c{drawing} structure (a \q{drawing object}). These objects are supplied as parameters to the back end's \cw{redraw()} and \cw{print()} functions. In fact these global functions are not implemented directly by the front end; instead, they are implemented centrally in \c{drawing.c} and form a small piece of middleware. The drawing API as supplied by the front end is a structure containing a set of function pointers, plus a \cq{void *} handle which is passed to each of those functions. This enables a single front end to switch between multiple implementations of the drawing API if necessary. For example, the Windows API supplies a printing mechanism integrated into the same GDI which deals with drawing in windows, and therefore the same API implementation can handle both drawing and printing; but on Unix, the most common way for applications to print is by producing PostScript output directly, and although it would be \e{possible} to write a single (say) \cw{draw_rect()} function which checked a global flag to decide whether to do GTK drawing operations or output PostScript to a file, it's much nicer to have two separate functions and switch between them as appropriate. When drawing, the puzzle window is indexed by pixel coordinates, with the top left pixel defined as \cw{(0,0)} and the bottom right pixel \cw{(w-1,h-1)}, where \c{w} and \c{h} are the width and height values returned by the back end function \cw{compute_size()} (\k{backend-compute-size}). When printing, the puzzle's print area is indexed in exactly the same way (with an arbitrary tile size provided by the printing module \c{printing.c}), to facilitate sharing of code between the drawing and printing routines. However, when printing, puzzles may no longer assume that the coordinate unit has any relationship to a pixel; the printer's actual resolution might very well not even be known at print time, so the coordinate unit might be smaller or larger than a pixel. Puzzles' print functions should restrict themselves to drawing geometric shapes rather than fiddly pixel manipulation. \e{Puzzles' redraw functions may assume that the surface they draw on is persistent}. It is the responsibility of every front end to preserve the puzzle's window contents in the face of GUI window expose issues and similar. It is not permissible to request that the back end redraw any part of a window that it has already drawn, unless something has actually changed as a result of making moves in the puzzle. Most front ends accomplish this by having the drawing routines draw on a stored bitmap rather than directly on the window, and copying the bitmap to the window every time a part of the window needs to be redrawn. Therefore, it is vitally important that whenever the back end does any drawing it informs the front end of which parts of the window it has accessed, and hence which parts need repainting. This is done by calling \cw{draw_update()} (\k{drawing-draw-update}). Persistence of old drawing is convenient. However, a puzzle should be very careful about how it updates its drawing area. The problem is that some front ends do anti-aliased drawing: rather than simply choosing between leaving each pixel untouched or painting it a specified colour, an antialiased drawing function will \e{blend} the original and new colours in pixels at a figure's boundary according to the proportion of the pixel occupied by the figure (probably modified by some heuristic fudge factors). All of this produces a smoother appearance for curves and diagonal lines. An unfortunate effect of drawing an anti-aliased figure repeatedly is that the pixels around the figure's boundary come steadily more saturated with \q{ink} and the boundary appears to \q{spread out}. Worse, redrawing a figure in a different colour won't fully paint over the old boundary pixels, so the end result is a rather ugly smudge. A good strategy to avoid unpleasant anti-aliasing artifacts is to identify a number of rectangular areas which need to be redrawn, clear them to the background colour, and then redraw their contents from scratch, being careful all the while not to stray beyond the boundaries of the original rectangles. The \cw{clip()} function (\k{drawing-clip}) comes in very handy here. Games based on a square grid can often do this fairly easily. Other games may need to be somewhat more careful. For example, Loopy's redraw function first identifies portions of the display which need to be updated. Then, if the changes are fairly well localised, it clears and redraws a rectangle containing each changed area. Otherwise, it gives up and redraws the entire grid from scratch. It is possible to avoid clearing to background and redrawing from scratch if one is very careful about which drawing functions one uses: if a function is documented as not anti-aliasing under some circumstances, you can rely on each pixel in a drawing either being left entirely alone or being set to the requested colour, with no blending being performed. In the following sections I first discuss the drawing API as seen by the back end, and then the \e{almost} identical function-pointer form seen by the front end. \H{drawing-backend} Drawing API as seen by the back end This section documents the back-end drawing API, in the form of functions which take a \c{drawing} object as an argument. \S{drawing-draw-rect} \cw{draw_rect()} \c void draw_rect(drawing *dr, int x, int y, int w, int h, \c int colour); Draws a filled rectangle in the puzzle window. \c{x} and \c{y} give the coordinates of the top left pixel of the rectangle. \c{w} and \c{h} give its width and height. Thus, the horizontal extent of the rectangle runs from \c{x} to \c{x+w-1} inclusive, and the vertical extent from \c{y} to \c{y+h-1} inclusive. \c{colour} is an integer index into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). There is no separate pixel-plotting function. If you want to plot a single pixel, the approved method is to use \cw{draw_rect()} with width and height set to 1. Unlike many of the other drawing functions, this function is guaranteed to be pixel-perfect: the rectangle will be sharply defined and not anti-aliased or anything like that. This function may be used for both drawing and printing. \S{drawing-draw-rect-outline} \cw{draw_rect_outline()} \c void draw_rect_outline(drawing *dr, int x, int y, int w, int h, \c int colour); Draws an outline rectangle in the puzzle window. \c{x} and \c{y} give the coordinates of the top left pixel of the rectangle. \c{w} and \c{h} give its width and height. Thus, the horizontal extent of the rectangle runs from \c{x} to \c{x+w-1} inclusive, and the vertical extent from \c{y} to \c{y+h-1} inclusive. \c{colour} is an integer index into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). From a back end perspective, this function may be considered to be part of the drawing API. However, front ends are not required to implement it, since it is actually implemented centrally (in \cw{misc.c}) as a wrapper on \cw{draw_polygon()}. This function may be used for both drawing and printing. \S{drawing-draw-rect-corner} \cw{draw_rect_corners()} \c void draw_rect_corners(drawing *dr, int cx, int cy, int r, int col); Draws four L-shapes at the corners of a square, in the manner of a target reticule. This is a convenience function for back ends to use to display a keyboard cursor (if they want one in that style). \c{cx} and \c{cy} give the coordinates of the centre of the square. \c{r} is half the side length of the square, so that the corners are at \cw{(cx-r,cy-r)}, \cw{(cx+r,cy-r)}, \cw{(cx-r,cy+r)} and \cw{(cx+r,cy+r)}. \c{colour} is an integer index into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). \S{drawing-draw-line} \cw{draw_line()} \c void draw_line(drawing *dr, int x1, int y1, int x2, int y2, \c int colour); Draws a straight line in the puzzle window. \c{x1} and \c{y1} give the coordinates of one end of the line. \c{x2} and \c{y2} give the coordinates of the other end. The line drawn includes both those points. \c{colour} is an integer index into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). Some platforms may perform anti-aliasing on this function. Therefore, do not assume that you can erase a line by drawing the same line over it in the background colour; anti-aliasing might lead to perceptible ghost artefacts around the vanished line. Horizontal and vertical lines, however, are pixel-perfect and not anti-aliased. This function may be used for both drawing and printing. \S{drawing-draw-polygon} \cw{draw_polygon()} \c void draw_polygon(drawing *dr, const int *coords, int npoints, \c int fillcolour, int outlinecolour); Draws an outlined or filled polygon in the puzzle window. \c{coords} is an array of \cw{(2*npoints)} integers, containing the \c{x} and \c{y} coordinates of \c{npoints} vertices. \c{fillcolour} and \c{outlinecolour} are integer indices into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). \c{fillcolour} may also be \cw{-1} to indicate that the polygon should be outlined only. The polygon defined by the specified list of vertices is first filled in \c{fillcolour}, if specified, and then outlined in \c{outlinecolour}. \c{outlinecolour} may \e{not} be \cw{-1}; it must be a valid colour (and front ends are permitted to enforce this by assertion). This is because different platforms disagree on whether a filled polygon should include its boundary line or not, so drawing \e{only} a filled polygon would have non-portable effects. If you want your filled polygon not to have a visible outline, you must set \c{outlinecolour} to the same as \c{fillcolour}. Some platforms may perform anti-aliasing on this function. Therefore, do not assume that you can erase a polygon by drawing the same polygon over it in the background colour. Also, be prepared for the polygon to extend a pixel beyond its obvious bounding box as a result of this; if you really need it not to do this to avoid interfering with other delicate graphics, you should probably use \cw{clip()} (\k{drawing-clip}). You can rely on horizontal and vertical lines not being anti-aliased. This function may be used for both drawing and printing. \S{drawing-draw-circle} \cw{draw_circle()} \c void draw_circle(drawing *dr, int cx, int cy, int radius, \c int fillcolour, int outlinecolour); Draws an outlined or filled circle in the puzzle window. \c{cx} and \c{cy} give the coordinates of the centre of the circle. \c{radius} gives its radius. The total horizontal pixel extent of the circle is from \c{cx-radius+1} to \c{cx+radius-1} inclusive, and the vertical extent similarly around \c{cy}. \c{fillcolour} and \c{outlinecolour} are integer indices into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). \c{fillcolour} may also be \cw{-1} to indicate that the circle should be outlined only. The circle is first filled in \c{fillcolour}, if specified, and then outlined in \c{outlinecolour}. \c{outlinecolour} may \e{not} be \cw{-1}; it must be a valid colour (and front ends are permitted to enforce this by assertion). This is because different platforms disagree on whether a filled circle should include its boundary line or not, so drawing \e{only} a filled circle would have non-portable effects. If you want your filled circle not to have a visible outline, you must set \c{outlinecolour} to the same as \c{fillcolour}. Some platforms may perform anti-aliasing on this function. Therefore, do not assume that you can erase a circle by drawing the same circle over it in the background colour. Also, be prepared for the circle to extend a pixel beyond its obvious bounding box as a result of this; if you really need it not to do this to avoid interfering with other delicate graphics, you should probably use \cw{clip()} (\k{drawing-clip}). This function may be used for both drawing and printing. \S{drawing-draw-thick-line} \cw{draw_thick_line()} \c void draw_thick_line(drawing *dr, float thickness, \c float x1, float y1, float x2, float y2, \c int colour) Draws a line in the puzzle window, giving control over the line's thickness. \c{x1} and \c{y1} give the coordinates of one end of the line. \c{x2} and \c{y2} give the coordinates of the other end. \c{thickness} gives the thickness of the line, in pixels. Note that the coordinates and thickness are floating-point: the continuous coordinate system is in effect here. It's important to be able to address points with better-than-pixel precision in this case, because one can't otherwise properly express the endpoints of lines with both odd and even thicknesses. Some platforms may perform anti-aliasing on this function. The precise pixels affected by a thick-line drawing operation may vary between platforms, and no particular guarantees are provided. Indeed, even horizontal or vertical lines may be anti-aliased. This function may be used for both drawing and printing. If the specified thickness is less than 1.0, 1.0 is used. This ensures that thin lines are visible even at small scales. \S{drawing-draw-text} \cw{draw_text()} \c void draw_text(drawing *dr, int x, int y, int fonttype, \c int fontsize, int align, int colour, \c const char *text); Draws text in the puzzle window. \c{x} and \c{y} give the coordinates of a point. The relation of this point to the location of the text is specified by \c{align}, which is a bitwise OR of horizontal and vertical alignment flags: \dt \cw{ALIGN_VNORMAL} \dd Indicates that \c{y} is aligned with the baseline of the text. \dt \cw{ALIGN_VCENTRE} \dd Indicates that \c{y} is aligned with the vertical centre of the text. (In fact, it's aligned with the vertical centre of normal \e{capitalised} text: displaying two pieces of text with \cw{ALIGN_VCENTRE} at the same \cw{y}-coordinate will cause their baselines to be aligned with one another, even if one is an ascender and the other a descender.) \dt \cw{ALIGN_HLEFT} \dd Indicates that \c{x} is aligned with the left-hand end of the text. \dt \cw{ALIGN_HCENTRE} \dd Indicates that \c{x} is aligned with the horizontal centre of the text. \dt \cw{ALIGN_HRIGHT} \dd Indicates that \c{x} is aligned with the right-hand end of the text. \c{fonttype} is either \cw{FONT_FIXED} or \cw{FONT_VARIABLE}, for a monospaced or proportional font respectively. (No more detail than that may be specified; it would only lead to portability issues between different platforms.) \c{fontsize} is the desired size, in pixels, of the text. This size corresponds to the overall point size of the text, not to any internal dimension such as the cap-height. \c{colour} is an integer index into the colours array returned by the back end function \cw{colours()} (\k{backend-colours}). This function may be used for both drawing and printing. The character set used to encode the text passed to this function is specified \e{by the drawing object}, although it must be a superset of ASCII. If a puzzle wants to display text that is not contained in ASCII, it should use the \cw{text_fallback()} function (\k{drawing-text-fallback}) to query the drawing object for an appropriate representation of the characters it wants. \S{drawing-text-fallback} \cw{text_fallback()} \c char *text_fallback(drawing *dr, const char *const *strings, \c int nstrings); This function is used to request a translation of UTF-8 text into whatever character encoding is expected by the drawing object's implementation of \cw{draw_text()}. The input is a list of strings encoded in UTF-8: \cw{nstrings} gives the number of strings in the list, and \cw{strings[0]}, \cw{strings[1]}, ..., \cw{strings[nstrings-1]} are the strings themselves. The returned string (which is dynamically allocated and must be freed when finished with) is derived from the first string in the list that the drawing object expects to be able to display reliably; it will consist of that string translated into the character set expected by \cw{draw_text()}. Drawing implementations are not required to handle anything outside ASCII, but are permitted to assume that \e{some} string will be successfully translated. So every call to this function must include a string somewhere in the list (presumably the last element) which consists of nothing but ASCII, to be used by any front end which cannot handle anything else. For example, if a puzzle wished to display a string including a multiplication sign (U+00D7 in Unicode, represented by the bytes C3 97 in UTF-8), it might do something like this: \c static const char *const times_signs[] = { "\xC3\x97", "x" }; \c char *times_sign = text_fallback(dr, times_signs, 2); \c sprintf(buffer, "%d%s%d", width, times_sign, height); \c sfree(times_sign); \c draw_text(dr, x, y, font, size, align, colour, buffer); \c sfree(buffer); which would draw a string with a times sign in the middle on platforms that support it, and fall back to a simple ASCII \cq{x} where there was no alternative. \S{drawing-clip} \cw{clip()} \c void clip(drawing *dr, int x, int y, int w, int h); Establishes a clipping rectangle in the puzzle window. \c{x} and \c{y} give the coordinates of the top left pixel of the clipping rectangle. \c{w} and \c{h} give its width and height. Thus, the horizontal extent of the rectangle runs from \c{x} to \c{x+w-1} inclusive, and the vertical extent from \c{y} to \c{y+h-1} inclusive. (These are exactly the same semantics as \cw{draw_rect()}.) After this call, no drawing operation will affect anything outside the specified rectangle. The effect can be reversed by calling \cw{unclip()} (\k{drawing-unclip}). The clipping rectangle is pixel-perfect: pixels within the rectangle are affected as usual by drawing functions; pixels outside are completely untouched. Back ends should not assume that a clipping rectangle will be automatically cleared up by the front end if it's left lying around; that might work on current front ends, but shouldn't be relied upon. Always explicitly call \cw{unclip()}. This function may be used for both drawing and printing. \S{drawing-unclip} \cw{unclip()} \c void unclip(drawing *dr); Reverts the effect of a previous call to \cw{clip()}. After this call, all drawing operations will be able to affect the entire puzzle window again. This function may be used for both drawing and printing. \S{drawing-draw-update} \cw{draw_update()} \c void draw_update(drawing *dr, int x, int y, int w, int h); Informs the front end that a rectangular portion of the puzzle window has been drawn on and needs to be updated. \c{x} and \c{y} give the coordinates of the top left pixel of the update rectangle. \c{w} and \c{h} give its width and height. Thus, the horizontal extent of the rectangle runs from \c{x} to \c{x+w-1} inclusive, and the vertical extent from \c{y} to \c{y+h-1} inclusive. (These are exactly the same semantics as \cw{draw_rect()}.) The back end redraw function \e{must} call this function to report any changes it has made to the window. Otherwise, those changes may not become immediately visible, and may then appear at an unpredictable subsequent time such as the next time the window is covered and re-exposed. This function is only important when drawing. It may be called when printing as well, but doing so is not compulsory, and has no effect. (So if you have a shared piece of code between the drawing and printing routines, that code may safely call \cw{draw_update()}.) \S{drawing-status-bar} \cw{status_bar()} \c void status_bar(drawing *dr, const char *text); Sets the text in the game's status bar to \c{text}. The text is copied from the supplied buffer, so the caller is free to deallocate or modify the buffer after use. (This function is not exactly a \e{drawing} function, but it shares with the drawing API the property that it may only be called from within the back end redraw function. And it's implemented by front ends via the \c{drawing_api} function pointer table. So this is the best place to document it.) The supplied text is filtered through the mid-end for optional rewriting before being passed on to the front end; the mid-end will prepend the current game time if the game is timed (and may in future perform other rewriting if it seems like a good idea). This function is for drawing only; it must never be called during printing. \S{drawing-blitter} Blitter functions This section describes a group of related functions which save and restore a section of the puzzle window. This is most commonly used to implement user interfaces involving dragging a puzzle element around the window: at the end of each call to \cw{redraw()}, if an object is currently being dragged, the back end saves the window contents under that location and then draws the dragged object, and at the start of the next \cw{redraw()} the first thing it does is to restore the background. The front end defines an opaque type called a \c{blitter}, which is capable of storing a rectangular area of a specified size. Blitter functions are for drawing only; they must never be called during printing. \S2{drawing-blitter-new} \cw{blitter_new()} \c blitter *blitter_new(drawing *dr, int w, int h); Creates a new blitter object which stores a rectangle of size \c{w} by \c{h} pixels. Returns a pointer to the blitter object. Blitter objects are best stored in the \c{game_drawstate}. A good time to create them is in the \cw{set_size()} function (\k{backend-set-size}), since it is at this point that you first know how big a rectangle they will need to save. \S2{drawing-blitter-free} \cw{blitter_free()} \c void blitter_free(drawing *dr, blitter *bl); Disposes of a blitter object. Best called in \cw{free_drawstate()}. (However, check that the blitter object is not \cw{NULL} before attempting to free it; it is possible that a draw state might be created and freed without ever having \cw{set_size()} called on it in between.) \S2{drawing-blitter-save} \cw{blitter_save()} \c void blitter_save(drawing *dr, blitter *bl, int x, int y); This is a true drawing API function, in that it may only be called from within the game redraw routine. It saves a rectangular portion of the puzzle window into the specified blitter object. \c{x} and \c{y} give the coordinates of the top left corner of the saved rectangle. The rectangle's width and height are the ones specified when the blitter object was created. This function is required to cope and do the right thing if \c{x} and \c{y} are out of range. (The right thing probably means saving whatever part of the blitter rectangle overlaps with the visible area of the puzzle window.) \S2{drawing-blitter-load} \cw{blitter_load()} \c void blitter_load(drawing *dr, blitter *bl, int x, int y); This is a true drawing API function, in that it may only be called from within the game redraw routine. It restores a rectangular portion of the puzzle window from the specified blitter object. \c{x} and \c{y} give the coordinates of the top left corner of the rectangle to be restored. The rectangle's width and height are the ones specified when the blitter object was created. Alternatively, you can specify both \c{x} and \c{y} as the special value \cw{BLITTER_FROMSAVED}, in which case the rectangle will be restored to exactly where it was saved from. (This is probably what you want to do almost all the time, if you're using blitters to implement draggable puzzle elements.) This function is required to cope and do the right thing if \c{x} and \c{y} (or the equivalent ones saved in the blitter) are out of range. (The right thing probably means restoring whatever part of the blitter rectangle overlaps with the visible area of the puzzle window.) If this function is called on a blitter which had previously been saved from a partially out-of-range rectangle, then the parts of the saved bitmap which were not visible at save time are undefined. If the blitter is restored to a different position so as to make those parts visible, the effect on the drawing area is undefined. \S{print-mono-colour} \cw{print_mono_colour()} \c int print_mono_colour(drawing *dr, int grey); This function allocates a colour index for a simple monochrome colour during printing. \c{grey} must be 0 or 1. If \c{grey} is 0, the colour returned is black; if \c{grey} is 1, the colour is white. \S{print-grey-colour} \cw{print_grey_colour()} \c int print_grey_colour(drawing *dr, float grey); This function allocates a colour index for a grey-scale colour during printing. \c{grey} may be any number between 0 (black) and 1 (white); for example, 0.5 indicates a medium grey. The chosen colour will be rendered to the limits of the printer's halftoning capability. \S{print-hatched-colour} \cw{print_hatched_colour()} \c int print_hatched_colour(drawing *dr, int hatch); This function allocates a colour index which does not represent a literal \e{colour}. Instead, regions shaded in this colour will be hatched with parallel lines. The \c{hatch} parameter defines what type of hatching should be used in place of this colour: \dt \cw{HATCH_SLASH} \dd This colour will be hatched by lines slanting to the right at 45 degrees. \dt \cw{HATCH_BACKSLASH} \dd This colour will be hatched by lines slanting to the left at 45 degrees. \dt \cw{HATCH_HORIZ} \dd This colour will be hatched by horizontal lines. \dt \cw{HATCH_VERT} \dd This colour will be hatched by vertical lines. \dt \cw{HATCH_PLUS} \dd This colour will be hatched by criss-crossing horizontal and vertical lines. \dt \cw{HATCH_X} \dd This colour will be hatched by criss-crossing diagonal lines. Colours defined to use hatching may not be used for drawing lines or text; they may only be used for filling areas. That is, they may be used as the \c{fillcolour} parameter to \cw{draw_circle()} and \cw{draw_polygon()}, and as the colour parameter to \cw{draw_rect()}, but may not be used as the \c{outlinecolour} parameter to \cw{draw_circle()} or \cw{draw_polygon()}, or with \cw{draw_line()} or \cw{draw_text()}. \S{print-rgb-mono-colour} \cw{print_rgb_mono_colour()} \c int print_rgb_mono_colour(drawing *dr, float r, float g, \c float b, float grey); This function allocates a colour index for a fully specified RGB colour during printing. \c{r}, \c{g} and \c{b} may each be anywhere in the range from 0 to 1. If printing in black and white only, these values will be ignored, and either pure black or pure white will be used instead, according to the \q{grey} parameter. (The fallback colour is the same as the one which would be allocated by \cw{print_mono_colour(grey)}.) \S{print-rgb-grey-colour} \cw{print_rgb_grey_colour()} \c int print_rgb_grey_colour(drawing *dr, float r, float g, \c float b, float grey); This function allocates a colour index for a fully specified RGB colour during printing. \c{r}, \c{g} and \c{b} may each be anywhere in the range from 0 to 1. If printing in black and white only, these values will be ignored, and a shade of grey given by the \c{grey} parameter will be used instead. (The fallback colour is the same as the one which would be allocated by \cw{print_grey_colour(grey)}.) \S{print-rgb-hatched-colour} \cw{print_rgb_hatched_colour()} \c int print_rgb_hatched_colour(drawing *dr, float r, float g, \c float b, float hatched); This function allocates a colour index for a fully specified RGB colour during printing. \c{r}, \c{g} and \c{b} may each be anywhere in the range from 0 to 1. If printing in black and white only, these values will be ignored, and a form of cross-hatching given by the \c{hatch} parameter will be used instead; see \k{print-hatched-colour} for the possible values of this parameter. (The fallback colour is the same as the one which would be allocated by \cw{print_hatched_colour(hatch)}.) \S{print-line-width} \cw{print_line_width()} \c void print_line_width(drawing *dr, int width); This function is called to set the thickness of lines drawn during printing. It is meaningless in drawing: all lines drawn by \cw{draw_line()}, \cw{draw_circle} and \cw{draw_polygon()} are one pixel in thickness. However, in printing there is no clear definition of a pixel and so line widths must be explicitly specified. The line width is specified in the usual coordinate system. Note, however, that it is a hint only: the central printing system may choose to vary line thicknesses at user request or due to printer capabilities. \S{print-line-dotted} \cw{print_line_dotted()} \c void print_line_dotted(drawing *dr, bool dotted); This function is called to toggle the drawing of dotted lines during printing. It is not supported during drawing. Setting \cq{dotted} to \cw{true} means that future lines drawn by \cw{draw_line()}, \cw{draw_circle} and \cw{draw_polygon()} will be dotted. Setting it to \cw{false} means that they will be solid. Some front ends may impose restrictions on the width of dotted lines. Asking for a dotted line via this front end will override any line width request if the front end requires it. \H{drawing-frontend} The drawing API as implemented by the front end This section describes the drawing API in the function-pointer form in which it is implemented by a front end. (It isn't only platform-specific front ends which implement this API; the platform-independent module \c{ps.c} also provides an implementation of it which outputs PostScript. Thus, any platform which wants to do PS printing can do so with minimum fuss.) The following entries all describe function pointer fields in a structure called \c{drawing_api}. Each of the functions takes a \cq{void *} context pointer, which it should internally cast back to a more useful type. Thus, a drawing \e{object} (\c{drawing *)} suitable for passing to the back end redraw or printing functions is constructed by passing a \c{drawing_api} and a \cq{void *} to the function \cw{drawing_new()} (see \k{drawing-new}). \S{drawingapi-draw-text} \cw{draw_text()} \c void (*draw_text)(void *handle, int x, int y, int fonttype, \c int fontsize, int align, int colour, \c const char *text); This function behaves exactly like the back end \cw{draw_text()} function; see \k{drawing-draw-text}. \S{drawingapi-draw-rect} \cw{draw_rect()} \c void (*draw_rect)(void *handle, int x, int y, int w, int h, \c int colour); This function behaves exactly like the back end \cw{draw_rect()} function; see \k{drawing-draw-rect}. \S{drawingapi-draw-line} \cw{draw_line()} \c void (*draw_line)(void *handle, int x1, int y1, int x2, int y2, \c int colour); This function behaves exactly like the back end \cw{draw_line()} function; see \k{drawing-draw-line}. \S{drawingapi-draw-polygon} \cw{draw_polygon()} \c void (*draw_polygon)(void *handle, const int *coords, int npoints, \c int fillcolour, int outlinecolour); This function behaves exactly like the back end \cw{draw_polygon()} function; see \k{drawing-draw-polygon}. \S{drawingapi-draw-circle} \cw{draw_circle()} \c void (*draw_circle)(void *handle, int cx, int cy, int radius, \c int fillcolour, int outlinecolour); This function behaves exactly like the back end \cw{draw_circle()} function; see \k{drawing-draw-circle}. \S{drawingapi-draw-thick-line} \cw{draw_thick_line()} \c void draw_thick_line(drawing *dr, float thickness, \c float x1, float y1, float x2, float y2, \c int colour) This function behaves exactly like the back end \cw{draw_thick_line()} function; see \k{drawing-draw-thick-line}. An implementation of this API which doesn't provide high-quality rendering of thick lines is permitted to define this function pointer to be \cw{NULL}. The middleware in \cw{drawing.c} will notice and provide a low-quality alternative using \cw{draw_polygon()}. \S{drawingapi-draw-update} \cw{draw_update()} \c void (*draw_update)(void *handle, int x, int y, int w, int h); This function behaves exactly like the back end \cw{draw_update()} function; see \k{drawing-draw-update}. An implementation of this API which only supports printing is permitted to define this function pointer to be \cw{NULL} rather than bothering to define an empty function. The middleware in \cw{drawing.c} will notice and avoid calling it. \S{drawingapi-clip} \cw{clip()} \c void (*clip)(void *handle, int x, int y, int w, int h); This function behaves exactly like the back end \cw{clip()} function; see \k{drawing-clip}. \S{drawingapi-unclip} \cw{unclip()} \c void (*unclip)(void *handle); This function behaves exactly like the back end \cw{unclip()} function; see \k{drawing-unclip}. \S{drawingapi-start-draw} \cw{start_draw()} \c void (*start_draw)(void *handle); This function is called at the start of drawing. It allows the front end to initialise any temporary data required to draw with, such as device contexts. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-end-draw} \cw{end_draw()} \c void (*end_draw)(void *handle); This function is called at the end of drawing. It allows the front end to do cleanup tasks such as deallocating device contexts and scheduling appropriate GUI redraw events. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-status-bar} \cw{status_bar()} \c void (*status_bar)(void *handle, const char *text); This function behaves exactly like the back end \cw{status_bar()} function; see \k{drawing-status-bar}. Front ends implementing this function need not worry about it being called repeatedly with the same text; the middleware code in \cw{status_bar()} will take care of this. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-blitter-new} \cw{blitter_new()} \c blitter *(*blitter_new)(void *handle, int w, int h); This function behaves exactly like the back end \cw{blitter_new()} function; see \k{drawing-blitter-new}. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-blitter-free} \cw{blitter_free()} \c void (*blitter_free)(void *handle, blitter *bl); This function behaves exactly like the back end \cw{blitter_free()} function; see \k{drawing-blitter-free}. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-blitter-save} \cw{blitter_save()} \c void (*blitter_save)(void *handle, blitter *bl, int x, int y); This function behaves exactly like the back end \cw{blitter_save()} function; see \k{drawing-blitter-save}. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-blitter-load} \cw{blitter_load()} \c void (*blitter_load)(void *handle, blitter *bl, int x, int y); This function behaves exactly like the back end \cw{blitter_load()} function; see \k{drawing-blitter-load}. Implementations of this API which do not provide drawing services may define this function pointer to be \cw{NULL}; it will never be called unless drawing is attempted. \S{drawingapi-begin-doc} \cw{begin_doc()} \c void (*begin_doc)(void *handle, int pages); This function is called at the beginning of a printing run. It gives the front end an opportunity to initialise any required printing subsystem. It also provides the number of pages in advance. Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-begin-page} \cw{begin_page()} \c void (*begin_page)(void *handle, int number); This function is called during printing, at the beginning of each page. It gives the page number (numbered from 1 rather than 0, so suitable for use in user-visible contexts). Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-begin-puzzle} \cw{begin_puzzle()} \c void (*begin_puzzle)(void *handle, float xm, float xc, \c float ym, float yc, int pw, int ph, float wmm); This function is called during printing, just before printing a single puzzle on a page. It specifies the size and location of the puzzle on the page. \c{xm} and \c{xc} specify the horizontal position of the puzzle on the page, as a linear function of the page width. The front end is expected to multiply the page width by \c{xm}, add \c{xc} (measured in millimetres), and use the resulting x-coordinate as the left edge of the puzzle. Similarly, \c{ym} and \c{yc} specify the vertical position of the puzzle as a function of the page height: the page height times \c{ym}, plus \c{yc} millimetres, equals the desired distance from the top of the page to the top of the puzzle. (This unwieldy mechanism is required because not all printing systems can communicate the page size back to the software. The PostScript back end, for example, writes out PS which determines the page size at print time by means of calling \cq{clippath}, and centres the puzzles within that. Thus, exactly the same PS file works on A4 or on US Letter paper without needing local configuration, which simplifies matters.) \cw{pw} and \cw{ph} give the size of the puzzle in drawing API coordinates. The printing system will subsequently call the puzzle's own print function, which will in turn call drawing API functions in the expectation that an area \cw{pw} by \cw{ph} units is available to draw the puzzle on. Finally, \cw{wmm} gives the desired width of the puzzle in millimetres. (The aspect ratio is expected to be preserved, so if the desired puzzle height is also needed then it can be computed as \cw{wmm*ph/pw}.) Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-end-puzzle} \cw{end_puzzle()} \c void (*end_puzzle)(void *handle); This function is called after the printing of a specific puzzle is complete. Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-end-page} \cw{end_page()} \c void (*end_page)(void *handle, int number); This function is called after the printing of a page is finished. Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-end-doc} \cw{end_doc()} \c void (*end_doc)(void *handle); This function is called after the printing of the entire document is finished. This is the moment to close files, send things to the print spooler, or whatever the local convention is. Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-line-width} \cw{line_width()} \c void (*line_width)(void *handle, float width); This function is called to set the line thickness, during printing only. Note that the width is a \cw{float} here, where it was an \cw{int} as seen by the back end. This is because \cw{drawing.c} may have scaled it on the way past. However, the width is still specified in the same coordinate system as the rest of the drawing. Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-line-dotted} \cw{line_dotted()} \c void (*line_dotted)(void *handle, bool dotted); This function is called to toggle drawing of dotted lines, during printing only. Implementations of this API which do not provide printing services may define this function pointer to be \cw{NULL}; it will never be called unless printing is attempted. \S{drawingapi-text-fallback} \cw{text_fallback()} \c char *(*text_fallback)(void *handle, const char *const *strings, \c int nstrings); This function behaves exactly like the back end \cw{text_fallback()} function; see \k{drawing-text-fallback}. Implementations of this API which do not support any characters outside ASCII may define this function pointer to be \cw{NULL}, in which case the central code in \cw{drawing.c} will provide a default implementation. \H{drawingapi-frontend} The drawing API as called by the front end There are a small number of functions provided in \cw{drawing.c} which the front end needs to \e{call}, rather than helping to implement. They are described in this section. \S{drawing-new} \cw{drawing_new()} \c drawing *drawing_new(const drawing_api *api, midend *me, \c void *handle); This function creates a drawing object. It is passed a \c{drawing_api}, which is a structure containing nothing but function pointers; and also a \cq{void *} handle. The handle is passed back to each function pointer when it is called. The \c{midend} parameter is used for rewriting the status bar contents: \cw{status_bar()} (see \k{drawing-status-bar}) has to call a function in the mid-end which might rewrite the status bar text. If the drawing object is to be used only for printing, or if the game is known not to call \cw{status_bar()}, this parameter may be \cw{NULL}. \S{drawing-free} \cw{drawing_free()} \c void drawing_free(drawing *dr); This function frees a drawing object. Note that the \cq{void *} handle is not freed; if that needs cleaning up it must be done by the front end. \S{drawing-print-get-colour} \cw{print_get_colour()} \c void print_get_colour(drawing *dr, int colour, bool printing_in_colour, \c int *hatch, float *r, float *g, float *b); This function is called by the implementations of the drawing API functions when they are called in a printing context. It takes a colour index as input, and returns the description of the colour as requested by the back end. \c{printing_in_colour} is \cw{true} iff the implementation is printing in colour. This will alter the results returned if the colour in question was specified with a black-and-white fallback value. If the colour should be rendered by hatching, \c{*hatch} is filled with the type of hatching desired. See \k{print-grey-colour} for details of the values this integer can take. If the colour should be rendered as solid colour, \c{*hatch} is given a negative value, and \c{*r}, \c{*g} and \c{*b} are filled with the RGB values of the desired colour (if printing in colour), or all filled with the grey-scale value (if printing in black and white). \C{midend} The API provided by the mid-end This chapter documents the API provided by the mid-end to be called by the front end. You probably only need to read this if you are a front end implementor, i.e. you are porting Puzzles to a new platform. If you're only interested in writing new puzzles, you can safely skip this chapter. All the persistent state in the mid-end is encapsulated within a \c{midend} structure, to facilitate having multiple mid-ends in any port which supports multiple puzzle windows open simultaneously. Each \c{midend} is intended to handle the contents of a single puzzle window. \H{midend-new} \cw{midend_new()} \c midend *midend_new(frontend *fe, const game *ourgame, \c const drawing_api *drapi, void *drhandle); Allocates and returns a new mid-end structure. The \c{fe} argument is stored in the mid-end. It will be used when calling back to functions such as \cw{activate_timer()} (\k{frontend-activate-timer}), and will be passed on to the back end function \cw{colours()} (\k{backend-colours}). The parameters \c{drapi} and \c{drhandle} are passed to \cw{drawing_new()} (\k{drawing-new}) to construct a drawing object which will be passed to the back end function \cw{redraw()} (\k{backend-redraw}). Hence, all drawing-related function pointers defined in \c{drapi} can expect to be called with \c{drhandle} as their first argument. The \c{ourgame} argument points to a container structure describing a game back end. The mid-end thus created will only be capable of handling that one game. (So even in a monolithic front end containing all the games, this imposes the constraint that any individual puzzle window is tied to a single game. Unless, of course, you feel brave enough to change the mid-end for the window without closing the window...) \H{midend-free} \cw{midend_free()} \c void midend_free(midend *me); Frees a mid-end structure and all its associated data. \H{midend-tilesize} \cw{midend_tilesize()} \c int midend_tilesize(midend *me); Returns the \cq{tilesize} parameter being used to display the current puzzle (\k{backend-preferred-tilesize}). \H{midend-set-params} \cw{midend_set_params()} \c void midend_set_params(midend *me, game_params *params); Sets the current game parameters for a mid-end. Subsequent games generated by \cw{midend_new_game()} (\k{midend-new-game}) will use these parameters until further notice. The usual way in which the front end will have an actual \c{game_params} structure to pass to this function is if it had previously got it from \cw{midend_get_presets()} (\k{midend-get-presets}). Thus, this function is usually called in response to the user making a selection from the presets menu. \H{midend-get-params} \cw{midend_get_params()} \c game_params *midend_get_params(midend *me); Returns the current game parameters stored in this mid-end. The returned value is dynamically allocated, and should be freed when finished with by passing it to the game's own \cw{free_params()} function (see \k{backend-free-params}). \H{midend-size} \cw{midend_size()} \c void midend_size(midend *me, int *x, int *y, bool user_size, double device_pixel_ratio); Tells the mid-end to figure out its window size. On input, \c{*x} and \c{*y} should contain the maximum or requested size for the window. (Typically this will be the size of the screen that the window has to fit on, or similar.) The mid-end will repeatedly call the back end function \cw{compute_size()} (\k{backend-compute-size}), searching for a tile size that best satisfies the requirements. On exit, \c{*x} and \c{*y} will contain the size needed for the puzzle window's drawing area. (It is of course up to the front end to adjust this for any additional window furniture such as menu bars and window borders, if necessary. The status bar is also not included in this size.) Use \c{user_size} to indicate whether \c{*x} and \c{*y} are a requested size, or just a maximum size. If \c{user_size} is set to \cw{true}, the mid-end will treat the input size as a request, and will pick a tile size which approximates it \e{as closely as possible}, going over the game's preferred tile size if necessary to achieve this. The mid-end will also use the resulting tile size as its preferred one until further notice, on the assumption that this size was explicitly requested by the user. Use this option if you want your front end to support dynamic resizing of the puzzle window with automatic scaling of the puzzle to fit. If \c{user_size} is set to \cw{false}, then the game's tile size will never go over its preferred one, although it may go under in order to fit within the maximum bounds specified by \c{*x} and \c{*y}. This is the recommended approach when opening a new window at default size: the game will use its preferred size unless it has to use a smaller one to fit on the screen. If the tile size is shrunk for this reason, the change will not persist; if a smaller grid is subsequently chosen, the tile size will recover. The mid-end will try as hard as it can to return a size which is less than or equal to the input size, in both dimensions. In extreme circumstances it may fail (if even the lowest possible tile size gives window dimensions greater than the input), in which case it will return a size greater than the input size. Front ends should be prepared for this to happen (i.e. don't crash or fail an assertion), but may handle it in any way they see fit: by rejecting the game parameters which caused the problem, by opening a window larger than the screen regardless of inconvenience, by introducing scroll bars on the window, by drawing on a large bitmap and scaling it into a smaller window, or by any other means you can think of. It is likely that when the tile size is that small the game will be unplayable anyway, so don't put \e{too} much effort into handling it creatively. If your platform has no limit on window size (or if you're planning to use scroll bars for large puzzles), you can pass dimensions of \cw{INT_MAX} as input to this function. You should probably not do that \e{and} set the \c{user_size} flag, though! The \cw{device_pixel_ratio} allows the front end to specify that its pixels are unusually large or small (or should be treated as such). The mid-end uses this to adjust the tile size, both at startup (if the ratio is not 1) and if the ratio changes. A \cw{device_pixel_ratio} of 1 indicates normal-sized pixels. \q{Normal} is not precisely defined, but it's about 4 pixels per millimetre on a screen designed to be viewed from a metre away, or a size such that text 15 pixels high is comfortably readable. Some platforms have a concept of a logical pixel that this can be mapped onto. For instance, Cascading Style Sheets (CSS) has a unit called \cq{px} that only matches physical pixels at a \cw{device_pixel_ratio} of 1. The \cw{device_pixel_ratio} indicates the number of physical pixels in a normal-sized pixel, so values less than 1 indicate unusually large pixels and values greater than 1 indicate unusually small pixels. The midend relies on the frontend calling \cw{midend_new_game()} (\k{midend-new-game}) before calling \cw{midend_size()}. \H{midend-reset-tilesize} \cw{midend_reset_tilesize()} \c void midend_reset_tilesize(midend *me); This function resets the midend's preferred tile size to that of the standard puzzle. As discussed in \k{midend-size}, puzzle resizes are typically 'sticky', in that once the user has dragged the puzzle to a different window size, the resulting tile size will be remembered and used when the puzzle configuration changes. If you \e{don't} want that, e.g. if you want to provide a command to explicitly reset the puzzle size back to its default, then you can call this just before calling \cw{midend_size()} (which, in turn, you would probably call with \c{user_size} set to \cw{false}). \H{midend-new-game} \cw{midend_new_game()} \c void midend_new_game(midend *me); Causes the mid-end to begin a new game. Normally the game will be a new randomly generated puzzle. However, if you have previously called \cw{midend_game_id()} or \cw{midend_set_config()}, the game generated might be dictated by the results of those functions. (In particular, you \e{must} call \cw{midend_new_game()} after calling either of those functions, or else no immediate effect will be visible.) You will probably need to call \cw{midend_size()} after calling this function, because if the game parameters have been changed since the last new game then the window size might need to change. (If you know the parameters \e{haven't} changed, you don't need to do this.) This function will create a new \c{game_drawstate}, but does not actually perform a redraw (since you often need to call \cw{midend_size()} before the redraw can be done). So after calling this function and after calling \cw{midend_size()}, you should then call \cw{midend_redraw()}. (It is not necessary to call \cw{midend_force_redraw()}; that will discard the draw state and create a fresh one, which is unnecessary in this case since there's a fresh one already. It would work, but it's usually excessive.) \H{midend-restart-game} \cw{midend_restart_game()} \c void midend_restart_game(midend *me); This function causes the current game to be restarted. This is done by placing a new copy of the original game state on the end of the undo list (so that an accidental restart can be undone). This function automatically causes a redraw, i.e. the front end can expect its drawing API to be called from \e{within} a call to this function. Some back ends require that \cw{midend_size()} (\k{midend-size}) is called before \cw{midend_restart_game()}. \H{midend-force-redraw} \cw{midend_force_redraw()} \c void midend_force_redraw(midend *me); Forces a complete redraw of the puzzle window, by means of discarding the current \c{game_drawstate} and creating a new one from scratch before calling the game's \cw{redraw()} function. The front end can expect its drawing API to be called from within a call to this function. Some back ends require that \cw{midend_size()} (\k{midend-size}) is called before \cw{midend_force_redraw()}. \H{midend-redraw} \cw{midend_redraw()} \c void midend_redraw(midend *me); Causes a partial redraw of the puzzle window, by means of simply calling the game's \cw{redraw()} function. (That is, the only things redrawn will be things that have changed since the last redraw.) The front end can expect its drawing API to be called from within a call to this function. Some back ends require that \cw{midend_size()} (\k{midend-size}) is called before \cw{midend_redraw()}. \H{midend-process-key} \cw{midend_process_key()} \c bool midend_process_key(midend *me, int x, int y, int button, bool *handled); The front end calls this function to report a mouse or keyboard event. The parameters \c{x} and \c{y} are identical to the ones passed to the back end function \cw{interpret_move()} (\k{backend-interpret-move}). \c{button} is \e{almost} identical to the parameter passed to \cw{interpret_move()}. However, some additional special button values are defined for the front end to pass to the midend (see below). Also, the front end is \e{not} required to provide guarantees about mouse event ordering. The mid-end will sort out multiple simultaneous button presses and changes of button; the front end's responsibility is simply to pass on the mouse events it receives as accurately as possible. (Some platforms may need to emulate absent mouse buttons by means of using a modifier key such as Shift with another mouse button. This tends to mean that if Shift is pressed or released in the middle of a mouse drag, the mid-end will suddenly stop receiving, say, \cw{LEFT_DRAG} events and start receiving \cw{RIGHT_DRAG}s, with no intervening button release or press events. This too is something which the mid-end will sort out for you; the front end has no obligation to maintain sanity in this area.) The front end \e{should}, however, always eventually send some kind of button release. On some platforms this requires special effort: Windows, for example, requires a call to the system API function \cw{SetCapture()} in order to ensure that your window receives a mouse-up event even if the pointer has left the window by the time the mouse button is released. On any platform that requires this sort of thing, the front end \e{is} responsible for doing it. Calling this function is very likely to result in calls back to the front end's drawing API and/or \cw{activate_timer()} (\k{frontend-activate-timer}). The return value from \cw{midend_process_key()} is \cw{true} unless the effect of the keypress was to request termination of the program. A front end should shut down the puzzle in response to a \cw{false} return. If the front end passes in a non-NULL pointer in \c{handled}, the mid-end will set \cw{*handled} to \cw{true} if it or the backend does something in response to the keypress. A front end can use this to decide whether to pass the keypress on to anything else that might want to do something in response to it. The following additional values of \c{button} are permitted to be passed to this function by the front end, but are never passed on to the back end. They indicate front-end specific UI operations, such as selecting an option from a drop-down menu. (Otherwise the front end would have to translate the \q{New Game} menu item into an \cq{n} keypress, for example.) \dt \cw{UI_NEWGAME} \dd Indicates that the user requested a new game, similar to pressing \cq{n}. \dt \cw{UI_SOLVE} \dd Indicates that the user requested the solution of the current game. \dt \cw{UI_UNDO} \dd Indicates that the user attempted to undo a move. \dt \cw{UI_REDO} \dd Indicates that the user attempted to redo an undone move. \dt \cw{UI_QUIT} \dd Indicates that the user asked to quit the game. (Of course, a front end might perfectly well handle this on its own. But including it in this enumeration allows the front end to treat all these menu items the same, by translating each of them into a button code passed to the midend, and handle quitting by noticing the \c{false} return value from \cw{midend_process_key()}.) \H{midend-request-keys} \cw{midend_request_keys()} \c key_label *midend_request_keys(midend *me, int *nkeys); This function behaves similarly to the backend's \cw{request_keys()} function (\k{backend-request-keys}). If the backend does not provide \cw{request_keys()}, this function will return \cw{NULL} and set \cw{*nkeys} to zero. Otherwise, this function will fill in the generic labels (i.e. the \cw{key_label} items that have their \cw{label} fields set to \cw{NULL}) by using \cw{button2label()} (\k{utils-button2label}). \H{midend-current-key-label} \cw{midend_current_key_label()} \c const char *midend_current_key_label(midend *me, int button); This is a thin wrapper around the backend's \cw{current_key_label()} function (\k{backend-current-key-label}). Front ends that need to label \cw{CURSOR_SELECT} or \cw{CURSOR_SELECT2} should call this function after each move (at least after each call to \cw{midend_process_key()}) to get the current labels. The front end should arrange to copy the returned string somewhere before the next call to the mid-end, just in case it's dynamically allocated. If the button supplied does nothing, the label returned will be an empty string. \H{midend-colours} \cw{midend_colours()} \c float *midend_colours(midend *me, int *ncolours); Returns an array of the colours required by the game, in exactly the same format as that returned by the back end function \cw{colours()} (\k{backend-colours}). Front ends should call this function rather than calling the back end's version directly, since the mid-end adds standard customisation facilities. (At the time of writing, those customisation facilities are implemented hackily by means of environment variables, but it's not impossible that they may become more full and formal in future.) \H{midend-timer} \cw{midend_timer()} \c void midend_timer(midend *me, float tplus); If the mid-end has called \cw{activate_timer()} (\k{frontend-activate-timer}) to request regular callbacks for purposes of animation or timing, this is the function the front end should call on a regular basis. The argument \c{tplus} gives the time, in seconds, since the last time either this function was called or \cw{activate_timer()} was invoked. One of the major purposes of timing in the mid-end is to perform move animation. Therefore, calling this function is very likely to result in calls back to the front end's drawing API. \H{midend-get-presets} \cw{midend_get_presets()} \c struct preset_menu *midend_get_presets(midend *me, int *id_limit); Returns a data structure describing this game's collection of preset game parameters, organised into a hierarchical structure of menus and submenus. The return value is a pointer to a data structure containing the following fields (among others, which are not intended for front end use): \c struct preset_menu { \c int n_entries; \c struct preset_menu_entry *entries; \c /* and other things */ \e iiiiiiiiiiiiiiiiiiiiii \c }; Those fields describe the intended contents of one particular menu in the hierarchy. \cq{entries} points to an array of \cq{n_entries} items, each of which is a structure containing the following fields: \c struct preset_menu_entry { \c char *title; \c game_params *params; \c struct preset_menu *submenu; \c int id; \c }; Of these fields, \cq{title} and \cq{id} are present in every entry, giving (respectively) the textual name of the menu item and an integer identifier for it. The integer id will correspond to the one returned by \c{midend_which_preset} (\k{midend-which-preset}), when that preset is the one selected. The other two fields are mutually exclusive. Each \c{struct preset_menu_entry} will have one of those fields \cw{NULL} and the other one non-null. If the menu item is an actual preset, then \cq{params} will point to the set of game parameters that go with the name; if it's a submenu, then \cq{submenu} instead will be non-null, and will point at a subsidiary \c{struct preset_menu}. The complete hierarchy of these structures is owned by the mid-end, and will be freed when the mid-end is freed. The front end should not attempt to free any of it. The integer identifiers will be allocated densely from 0 upwards, so that it's reasonable for the front end to allocate an array which uses them as indices, if it needs to store information per preset menu item. For this purpose, the front end may pass the second parameter \cq{id_limit} to \cw{midend_get_presets} as the address of an \c{int} variable, into which \cw{midend_get_presets} will write an integer one larger than the largest id number actually used (i.e. the number of elements the front end would need in the array). Submenu-type entries also have integer identifiers. \H{midend-which-preset} \cw{midend_which_preset()} \c int midend_which_preset(midend *me); Returns the numeric index of the preset game parameter structure which matches the current game parameters, or a negative number if no preset matches. Front ends could use this to maintain a tick beside one of the items in the menu (or tick the \q{Custom} option if the return value is less than zero). The returned index value (if non-negative) will match the \c{id} field of the corresponding \cw{struct preset_menu_entry} returned by \c{midend_get_presets()} (\k{midend-get-presets}). \H{midend-wants-statusbar} \cw{midend_wants_statusbar()} \c bool midend_wants_statusbar(midend *me); This function returns \cw{true} if the puzzle has a use for a textual status line (to display score, completion status, currently active tiles, time, or anything else). Front ends should call this function rather than talking directly to the back end. \H{midend-get-config} \cw{midend_get_config()} \c config_item *midend_get_config(midend *me, int which, \c char **wintitle); Returns a dialog box description for user configuration. On input, \cw{which} should be set to one of three values, which select which of the various dialog box descriptions is returned: \dt \cw{CFG_SETTINGS} \dd Requests the GUI parameter configuration box generated by the puzzle itself. This should be used when the user selects \q{Custom} from the game types menu (or equivalent). The mid-end passes this request on to the back end function \cw{configure()} (\k{backend-configure}). \dt \cw{CFG_DESC} \dd Requests a box suitable for entering a descriptive game ID (and viewing the existing one). The mid-end generates this dialog box description itself. This should be used when the user selects \q{Specific} from the game menu (or equivalent). \dt \cw{CFG_SEED} \dd Requests a box suitable for entering a random-seed game ID (and viewing the existing one). The mid-end generates this dialog box description itself. This should be used when the user selects \q{Random Seed} from the game menu (or equivalent). (A fourth value \cw{CFG_FRONTEND_SPECIFIC} is provided in this enumeration, so that frontends can extend it for their own internal use. For example, you might wrap this function with a \cw{frontend_get_config} which handles some values of \c{which} itself and hands others on to the midend, depending on whether \cw{which < CFG_FRONTEND_SPECIFIC}.) The returned value is an array of \cw{config_item}s, exactly as described in \k{backend-configure}. Another returned value is an ASCII string giving a suitable title for the configuration window, in \c{*wintitle}. Both returned values are dynamically allocated and will need to be freed. The window title can be freed in the obvious way; the \cw{config_item} array is a slightly complex structure, so a utility function \cw{free_cfg()} is provided to free it for you. See \k{utils-free-cfg}. (Of course, you will probably not want to free the \cw{config_item} array until the dialog box is dismissed, because before then you will probably need to pass it to \cw{midend_set_config}.) \H{midend-set-config} \cw{midend_set_config()} \c const char *midend_set_config(midend *me, int which, \c config_item *cfg); Passes the mid-end the results of a configuration dialog box. \c{which} should have the same value which it had when \cw{midend_get_config()} was called; \c{cfg} should be the array of \c{config_item}s returned from \cw{midend_get_config()}, modified to contain the results of the user's editing operations. This function returns \cw{NULL} on success, or otherwise (if the configuration data was in some way invalid) an ASCII string containing an error message suitable for showing to the user. If the function succeeds, it is likely that the game parameters will have been changed and it is certain that a new game will be requested. The front end should therefore call \cw{midend_new_game()}, and probably also re-think the window size using \cw{midend_size()} and eventually perform a refresh using \cw{midend_redraw()}. \H{midend-game-id} \cw{midend_game_id()} \c const char *midend_game_id(midend *me, const char *id); Passes the mid-end a string game ID (of any of the valid forms \cq{params}, \cq{params:description} or \cq{params#seed}) which the mid-end will process and use for the next generated game. This function returns \cw{NULL} on success, or otherwise (if the configuration data was in some way invalid) an ASCII string containing an error message (not dynamically allocated) suitable for showing to the user. In the event of an error, the mid-end's internal state will be left exactly as it was before the call. If the function succeeds, it is likely that the game parameters will have been changed and it is certain that a new game will be requested. The front end should therefore call \cw{midend_new_game()}, and probably also re-think the window size using \cw{midend_size()} and eventually case a refresh using \cw{midend_redraw()}. \H{midend-get-game-id} \cw{midend_get_game_id()} \c char *midend_get_game_id(midend *me); Returns a descriptive game ID (i.e. one in the form \cq{params:description}) describing the game currently active in the mid-end. The returned string is dynamically allocated. \H{midend-get-random-seed} \cw{midend_get_random_seed()} \c char *midend_get_random_seed(midend *me); Returns a random game ID (i.e. one in the form \cq{params#seedstring}) describing the game currently active in the mid-end, if there is one. If the game was created by entering a description, no random seed will currently exist and this function will return \cw{NULL}. The returned string, if it is non-\cw{NULL}, is dynamically allocated. Unlike the descriptive game ID, the random seed can contain characters outside the printable ASCII set. \H{midend-can-format-as-text-now} \cw{midend_can_format_as_text_now()} \c bool midend_can_format_as_text_now(midend *me); Returns \cw{true} if the game code is capable of formatting puzzles of the currently selected game type as ASCII. If this returns \cw{false}, then \cw{midend_text_format()} (\k{midend-text-format}) will return \cw{NULL}. \H{midend-text-format} \cw{midend_text_format()} \c char *midend_text_format(midend *me); Formats the current game's current state as ASCII text suitable for copying to the clipboard. The returned string is dynamically allocated. If the game's \c{can_format_as_text_ever} flag is \cw{false}, or if its \cw{can_format_as_text_now()} function returns \cw{false}, then this function will return \cw{NULL}. If the returned string contains multiple lines (which is likely), it will use the normal C line ending convention (\cw{\\n} only). On platforms which use a different line ending convention for data in the clipboard, it is the front end's responsibility to perform the conversion. \H{midend-solve} \cw{midend_solve()} \c const char *midend_solve(midend *me); Requests the mid-end to perform a Solve operation. On success, \cw{NULL} is returned. On failure, an error message (not dynamically allocated) is returned, suitable for showing to the user. The front end can expect its drawing API and/or \cw{activate_timer()} to be called from within a call to this function. Some back ends require that \cw{midend_size()} (\k{midend-size}) is called before \cw{midend_solve()}. \H{midend-get-cursor-location} \cw{midend_get_cursor_location()} \c bool midend_get_cursor_location(midend *me, \c int *x, int *y, \c int *w, int *h); This function requests the location of the back end's on-screen cursor or other region of interest. What exactly this region contains is up to the backend, but in general the region will be an area that the player is controlling with the cursor keys \dash such as the player location in Cube and Inertia, or the cursor in any of the conventional grid-based games. With knowledge of this location, a front end can, for example, ensure that the region of interest remains visible even if the entire puzzle is too big to fit on the screen. On success, this function returns \cw{true}, and the locations pointed to by \cw{x}, \cw{y}, \cw{w} and \cw{h} are updated to describe the cursor region, which has an upper-left corner located at \cw{(*x,*y)} and a size of \cw{*w} pixels wide by \cw{*h} pixels tall. The caller may pass \cw{NULL} for any number of these pointers, which will be ignored. On failure, this function returns \cw{false}. Failure can occur if there is currently no active cursor region, or if the back end lacks cursor support. \H{midend-status} \cw{midend_status()} \c int midend_status(midend *me); This function returns +1 if the midend is currently displaying a game in a solved state, -1 if the game is in a permanently lost state, or 0 otherwise. This function just calls the back end's \cw{status()} function. Front ends may wish to use this as a cue to proactively offer the option of starting a new game. (See \k{backend-status} for more detail about the back end's \cw{status()} function and discussion of what should count as which status code.) \H{midend-can-undo} \cw{midend_can_undo()} \c bool midend_can_undo(midend *me); Returns \cw{true} if the midend is currently in a state where the undo operation is meaningful (i.e. at least one position exists on the undo chain before the present one). Front ends may wish to use this to visually activate and deactivate an undo button. \H{midend-can-redo} \cw{midend_can_redo()} \c bool midend_can_redo(midend *me); Returns \cw{true} if the midend is currently in a state where the redo operation is meaningful (i.e. at least one position exists on the redo chain after the present one). Front ends may wish to use this to visually activate and deactivate a redo button. \H{midend-serialise} \cw{midend_serialise()} \c void midend_serialise(midend *me, \c void (*write)(void *ctx, const void *buf, int len), void *wctx); Calling this function causes the mid-end to convert its entire internal state into a long ASCII text string, and to pass that string (piece by piece) to the supplied \c{write} function. The string will consist of printable ASCII characters and line feeds. Desktop implementations can use this function to save a game in any state (including half-finished) to a disk file, by supplying a \c{write} function which is a wrapper on \cw{fwrite()} (or local equivalent). Other implementations may find other uses for it, such as compressing the large and sprawling mid-end state into a manageable amount of memory when a palmtop application is suspended so that another one can run; in this case \cw{write} might want to write to a memory buffer rather than a file. There may be other uses for it as well. This function will call back to the supplied \c{write} function a number of times, with the first parameter (\c{ctx}) equal to \c{wctx}, and the other two parameters pointing at a piece of the output string. \H{midend-deserialise} \cw{midend_deserialise()} \c const char *midend_deserialise(midend *me, \c bool (*read)(void *ctx, void *buf, int len), void *rctx); This function is the counterpart to \cw{midend_serialise()}. It calls the supplied \cw{read} function repeatedly to read a quantity of data, and attempts to interpret that data as a serialised mid-end as output by \cw{midend_serialise()}. The \cw{read} function is called with the first parameter (\c{ctx}) equal to \c{rctx}, and should attempt to read \c{len} bytes of data into the buffer pointed to by \c{buf}. It should return \cw{false} on failure or \cw{true} on success. It should not report success unless it has filled the entire buffer; on platforms which might be reading from a pipe or other blocking data source, \c{read} is responsible for looping until the whole buffer has been filled. If the de-serialisation operation is successful, the mid-end's internal data structures will be replaced by the results of the load, and \cw{NULL} will be returned. Otherwise, the mid-end's state will be completely unchanged and an error message (typically some variation on \q{save file is corrupt}) will be returned. As usual, the error message string is not dynamically allocated. If this function succeeds, it is likely that the game parameters will have been changed. The front end should therefore probably re-think the window size using \cw{midend_size()}, and probably cause a refresh using \cw{midend_redraw()}. Because each mid-end is tied to a specific game back end, this function will fail if you attempt to read in a save file generated by a different game from the one configured in this mid-end, even if your application is a monolithic one containing all the puzzles. See \k{identify-game} for a helper function which will allow you to identify a save file before you instantiate your mid-end in the first place. \H{identify-game} \cw{identify_game()} \c const char *identify_game(char **name, \c bool (*read)(void *ctx, void *buf, int len), void *rctx); This function examines a serialised midend stream, of the same kind used by \cw{midend_serialise()} and \cw{midend_deserialise()}, and returns the \cw{name} field of the game back end from which it was saved. You might want this if your front end was a monolithic one containing all the puzzles, and you wanted to be able to load an arbitrary save file and automatically switch to the right game. Probably your next step would be to iterate through \cw{gamelist} (\k{frontend-backend}) looking for a game structure whose \cw{name} field matched the returned string, and give an error if you didn't find one. On success, the return value of this function is \cw{NULL}, and the game name string is written into \cw{*name}. The caller should free that string after using it. On failure, \cw{*name} is \cw{NULL}, and the return value is an error message (which does not need freeing at all). (This isn't strictly speaking a midend function, since it doesn't accept or return a pointer to a midend. You'd probably call it just \e{before} deciding what kind of midend you wanted to instantiate.) \H{midend-request-id-changes} \cw{midend_request_id_changes()} \c void midend_request_id_changes(midend *me, \c void (*notify)(void *), void *ctx); This function is called by the front end to request notification by the mid-end when the current game IDs (either descriptive or random-seed) change. This can occur as a result of keypresses ('n' for New Game, for example) or when a puzzle supersedes its game description (see \k{backend-supersede}). After this function is called, any change of the game ids will cause the mid-end to call \cw{notify(ctx)} after the change. This is for use by puzzles which want to present the game description to the user constantly (e.g. as an HTML hyperlink) instead of only showing it when the user explicitly requests it. This is a function I anticipate few front ends needing to implement, so I make it a callback rather than a static function in order to relieve most front ends of the need to provide an empty implementation. \H{midend-which-game} \cw{midend_which_game()} \c const game *midend_which_preset(midend *me); This function returns the \c{game} structure for the puzzle type this midend is committed to. \H{frontend-backend} Direct reference to the back end structure by the front end Although \e{most} things the front end needs done should be done by calling the mid-end, there are a few situations in which the front end needs to refer directly to the game back end structure. The most obvious of these is \b passing the game back end as a parameter to \cw{midend_new()}. There are a few other back end features which are not wrapped by the mid-end because there didn't seem much point in doing so: \b fetching the \c{name} field to use in window titles and similar \b reading the \c{can_configure}, \c{can_solve} and \c{can_format_as_text_ever} fields to decide whether to add those items to the menu bar or equivalent \b reading the \c{winhelp_topic} field (Windows only) \b the GTK front end provides a \cq{--generate} command-line option which directly calls the back end to do most of its work. This is not really part of the main front end code, though, and I'm not sure it counts. In order to find the game back end structure, the front end does one of two things: \b If the particular front end is compiling a separate binary per game, then the back end structure is a global variable with the standard name \cq{thegame}: \lcont{ \c extern const game thegame; } \b If the front end is compiled as a monolithic application containing all the puzzles together (in which case the preprocessor symbol \cw{COMBINED} must be defined when compiling most of the code base), then there will be two global variables defined: \lcont{ \c extern const game *gamelist[]; \c extern const int gamecount; \c{gamelist} will be an array of \c{gamecount} game structures, declared in the automatically constructed source module \c{list.c}. The application should search that array for the game it wants, probably by reaching into each game structure and looking at its \c{name} field. } \H{frontend-api} Mid-end to front-end calls This section describes the small number of functions which a front end must provide to be called by the mid-end or other standard utility modules. \H{frontend-get-random-seed} \cw{get_random_seed()} \c void get_random_seed(void **randseed, int *randseedsize); This function is called by a new mid-end, and also occasionally by game back ends. Its job is to return a piece of data suitable for using as a seed for initialisation of a new \c{random_state}. On exit, \c{*randseed} should be set to point at a newly allocated piece of memory containing some seed data, and \c{*randseedsize} should be set to the length of that data. A simple and entirely adequate implementation is to return a piece of data containing the current system time at the highest conveniently available resolution. \H{frontend-activate-timer} \cw{activate_timer()} \c void activate_timer(frontend *fe); This is called by the mid-end to request that the front end begin calling it back at regular intervals. The timeout interval is left up to the front end; the finer it is, the smoother move animations will be, but the more CPU time will be used. Current front ends use values around 20ms (i.e. 50Hz). After this function is called, the mid-end will expect to receive calls to \cw{midend_timer()} on a regular basis. \H{frontend-deactivate-timer} \cw{deactivate_timer()} \c void deactivate_timer(frontend *fe); This is called by the mid-end to request that the front end stop calling \cw{midend_timer()}. \H{frontend-fatal} \cw{fatal()} \c void fatal(const char *fmt, ...); This is called by some utility functions if they encounter a genuinely fatal error such as running out of memory. It is a variadic function in the style of \cw{printf()}, and is expected to show the formatted error message to the user any way it can and then terminate the application. It must not return. \H{frontend-default-colour} \cw{frontend_default_colour()} \c void frontend_default_colour(frontend *fe, float *output); This function expects to be passed a pointer to an array of three \cw{float}s. It returns the platform's local preferred background colour in those three floats, as red, green and blue values (in that order) ranging from \cw{0.0} to \cw{1.0}. This function should only ever be called by the back end function \cw{colours()} (\k{backend-colours}). (Thus, it isn't a \e{midend}-to-frontend function as such, but there didn't seem to be anywhere else particularly good to put it. Sorry.) \C{utils} Utility APIs This chapter documents a variety of utility APIs provided for the general use of the rest of the Puzzles code. \H{utils-random} Random number generation Platforms' local random number generators vary widely in quality and seed size. Puzzles therefore supplies its own high-quality random number generator, with the additional advantage of giving the same results if fed the same seed data on different platforms. This allows game random seeds to be exchanged between different ports of Puzzles and still generate the same games. Unlike the ANSI C \cw{rand()} function, the Puzzles random number generator has an \e{explicit} state object called a \c{random_state}. One of these is managed by each mid-end, for example, and passed to the back end to generate a game with. \S{utils-random-init} \cw{random_new()} \c random_state *random_new(char *seed, int len); Allocates, initialises and returns a new \c{random_state}. The input data is used as the seed for the random number stream (i.e. using the same seed at a later time will generate the same stream). The seed data can be any data at all; there is no requirement to use printable ASCII, or NUL-terminated strings, or anything like that. \S{utils-random-copy} \cw{random_copy()} \c random_state *random_copy(random_state *tocopy); Allocates a new \c{random_state}, copies the contents of another \c{random_state} into it, and returns the new state. If exactly the same sequence of functions is subsequently called on both the copy and the original, the results will be identical. This may be useful for speculatively performing some operation using a given random state, and later replaying that operation precisely. \S{utils-random-free} \cw{random_free()} \c void random_free(random_state *state); Frees a \c{random_state}. \S{utils-random-bits} \cw{random_bits()} \c unsigned long random_bits(random_state *state, int bits); Returns a random number from 0 to \cw{2^bits-1} inclusive. \c{bits} should be between 1 and 32 inclusive. \S{utils-random-upto} \cw{random_upto()} \c unsigned long random_upto(random_state *state, unsigned long limit); Returns a random number from 0 to \cw{limit-1} inclusive. \c{limit} may not be zero. \S{utils-random-state-encode} \cw{random_state_encode()} \c char *random_state_encode(random_state *state); Encodes the entire contents of a \c{random_state} in printable ASCII. Returns a dynamically allocated string containing that encoding. This can subsequently be passed to \cw{random_state_decode()} to reconstruct the same \c{random_state}. \S{utils-random-state-decode} \cw{random_state_decode()} \c random_state *random_state_decode(char *input); Decodes a string generated by \cw{random_state_encode()} and reconstructs an equivalent \c{random_state} to the one encoded, i.e. it should produce the same stream of random numbers. This function has no error reporting; if you pass it an invalid string it will simply generate an arbitrary random state, which may turn out to be noticeably non-random. \S{utils-shuffle} \cw{shuffle()} \c void shuffle(void *array, int nelts, int eltsize, random_state *rs); Shuffles an array into a random order. The interface is much like ANSI C \cw{qsort()}, except that there's no need for a compare function. \c{array} is a pointer to the first element of the array. \c{nelts} is the number of elements in the array; \c{eltsize} is the size of a single element (typically measured using \c{sizeof}). \c{rs} is a \c{random_state} used to generate all the random numbers for the shuffling process. \H{utils-presets} Presets menu management The function \c{midend_get_presets()} (\k{midend-get-presets}) returns a data structure describing a menu hierarchy. Back ends can also choose to provide such a structure to the mid-end, if they want to group their presets hierarchically. To make this easy, there are a few utility functions to construct preset menu structures, and also one intended for front-end use. \S{utils-preset-menu-new} \cw{preset_menu_new()} \c struct preset_menu *preset_menu_new(void); Allocates a new \c{struct preset_menu}, and initialises it to hold no menu items. \S{utils-preset-menu-add_submenu} \cw{preset_menu_add_submenu()} \c struct preset_menu *preset_menu_add_submenu \c (struct preset_menu *parent, char *title); Adds a new submenu to the end of an existing preset menu, and returns a pointer to a newly allocated \c{struct preset_menu} describing the submenu. The string parameter \cq{title} must be dynamically allocated by the caller. The preset-menu structure will take ownership of it, so the caller must not free it. \S{utils-preset-menu-add-preset} \cw{preset_menu_add_preset()} \c void preset_menu_add_preset \c (struct preset_menu *menu, char *title, game_params *params); Adds a preset game configuration to the end of a preset menu. Both the string parameter \cq{title} and the game parameter structure \cq{params} itself must be dynamically allocated by the caller. The preset-menu structure will take ownership of it, so the caller must not free it. \S{utils-preset-menu-lookup-by-id} \cw{preset_menu_lookup_by_id()} \c game_params *preset_menu_lookup_by_id \c (struct preset_menu *menu, int id); Given a numeric index, searches recursively through a preset menu hierarchy to find the corresponding menu entry, and returns a pointer to its existing \c{game_params} structure. This function is intended for front end use (but front ends need not use it if they prefer to do things another way). If a front end finds it inconvenient to store anything more than a numeric index alongside each menu item, then this function provides an easy way for the front end to get back the actual game parameters corresponding to a menu item that the user has selected. \H{utils-alloc} Memory allocation Puzzles has some central wrappers on the standard memory allocation functions, which provide compile-time type checking, and run-time error checking by means of quitting the application if it runs out of memory. This doesn't provide the best possible recovery from memory shortage, but on the other hand it greatly simplifies the rest of the code, because nothing else anywhere needs to worry about \cw{NULL} returns from allocation. \S{utils-snew} \cw{snew()} \c var = snew(type); \e iii iiii This macro takes a single argument which is a \e{type name}. It allocates space for one object of that type. If allocation fails it will call \cw{fatal()} and not return; so if it does return, you can be confident that its return value is non-\cw{NULL}. The return value is cast to the specified type, so that the compiler will type-check it against the variable you assign it into. Thus, this ensures you don't accidentally allocate memory the size of the wrong type and assign it into a variable of the right one (or vice versa!). \S{utils-snewn} \cw{snewn()} \c var = snewn(n, type); \e iii i iiii This macro is the array form of \cw{snew()}. It takes two arguments; the first is a number, and the second is a type name. It allocates space for that many objects of that type, and returns a type-checked non-\cw{NULL} pointer just as \cw{snew()} does. \S{utils-sresize} \cw{sresize()} \c var = sresize(var, n, type); \e iii iii i iiii This macro is a type-checked form of \cw{realloc()}. It takes three arguments: an input memory block, a new size in elements, and a type. It re-sizes the input memory block to a size sufficient to contain that many elements of that type. It returns a type-checked non-\cw{NULL} pointer, like \cw{snew()} and \cw{snewn()}. The input memory block can be \cw{NULL}, in which case this function will behave exactly like \cw{snewn()}. (In principle any ANSI-compliant \cw{realloc()} implementation ought to cope with this, but I've never quite trusted it to work everywhere.) \S{utils-sfree} \cw{sfree()} \c void sfree(void *p); This function is pretty much equivalent to \cw{free()}. It is provided with a dynamically allocated block, and frees it. The input memory block can be \cw{NULL}, in which case this function will do nothing. (In principle any ANSI-compliant \cw{free()} implementation ought to cope with this, but I've never quite trusted it to work everywhere.) \S{utils-dupstr} \cw{dupstr()} \c char *dupstr(const char *s); This function dynamically allocates a duplicate of a C string. Like the \cw{snew()} functions, it guarantees to return non-\cw{NULL} or not return at all. (Many platforms provide the function \cw{strdup()}. As well as guaranteeing never to return \cw{NULL}, my version has the advantage of being defined \e{everywhere}, rather than inconveniently not quite everywhere.) \S{utils-free-cfg} \cw{free_cfg()} \c void free_cfg(config_item *cfg); This function correctly frees an array of \c{config_item}s, including walking the array until it gets to the end and freeing any subsidiary data items in each \c{u} sub-union which are expected to be dynamically allocated. (See \k{backend-configure} for details of the \c{config_item} structure.) \S{utils-free-keys} \cw{free_keys()} \c void free_keys(key_label *keys, int nkeys); This function correctly frees an array of \c{key_label}s, including the dynamically allocated label string for each key. (See \k{backend-request-keys} for details of the \c{key_label} structure.) \H{utils-tree234} Sorted and counted tree functions Many games require complex algorithms for generating random puzzles, and some require moderately complex algorithms even during play. A common requirement during these algorithms is for a means of maintaining sorted or unsorted lists of items, such that items can be removed and added conveniently. For general use, Puzzles provides the following set of functions which maintain 2-3-4 trees in memory. (A 2-3-4 tree is a balanced tree structure, with the property that all lookups, insertions, deletions, splits and joins can be done in \cw{O(log N)} time.) All these functions expect you to be storing a tree of \c{void *} pointers. You can put anything you like in those pointers. By the use of per-node element counts, these tree structures have the slightly unusual ability to look elements up by their numeric index within the list represented by the tree. This means that they can be used to store an unsorted list (in which case, every time you insert a new element, you must explicitly specify the position where you wish to insert it). They can also do numeric lookups in a sorted tree, which might be useful for (for example) tracking the median of a changing data set. As well as storing sorted lists, these functions can be used for storing \q{maps} (associative arrays), by defining each element of a tree to be a (key, value) pair. \S{utils-newtree234} \cw{newtree234()} \c tree234 *newtree234(cmpfn234 cmp); Creates a new empty tree, and returns a pointer to it. The parameter \c{cmp} determines the sorting criterion on the tree. Its prototype is \c typedef int (*cmpfn234)(void *, void *); If you want a sorted tree, you should provide a function matching this prototype, which returns like \cw{strcmp()} does (negative if the first argument is smaller than the second, positive if it is bigger, zero if they compare equal). In this case, the function \cw{addpos234()} will not be usable on your tree (because all insertions must respect the sorting order). If you want an unsorted tree, pass \cw{NULL}. In this case you will not be able to use either \cw{add234()} or \cw{del234()}, or any other function such as \cw{find234()} which depends on a sorting order. Your tree will become something more like an array, except that it will efficiently support insertion and deletion as well as lookups by numeric index. \S{utils-freetree234} \cw{freetree234()} \c void freetree234(tree234 *t); Frees a tree. This function will not free the \e{elements} of the tree (because they might not be dynamically allocated, or you might be storing the same set of elements in more than one tree); it will just free the tree structure itself. If you want to free all the elements of a tree, you should empty it before passing it to \cw{freetree234()}, by means of code along the lines of \c while ((element = delpos234(tree, 0)) != NULL) \c sfree(element); /* or some more complicated free function */ \e iiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiiii \S{utils-add234} \cw{add234()} \c void *add234(tree234 *t, void *e); Inserts a new element \c{e} into the tree \c{t}. This function expects the tree to be sorted; the new element is inserted according to the sort order. If an element comparing equal to \c{e} is already in the tree, then the insertion will fail, and the return value will be the existing element. Otherwise, the insertion succeeds, and \c{e} is returned. \S{utils-addpos234} \cw{addpos234()} \c void *addpos234(tree234 *t, void *e, int index); Inserts a new element into an unsorted tree. Since there is no sorting order to dictate where the new element goes, you must specify where you want it to go. Setting \c{index} to zero puts the new element right at the start of the list; setting \c{index} to the current number of elements in the tree puts the new element at the end. Return value is \c{e}, in line with \cw{add234()} (although this function cannot fail except by running out of memory, in which case it will bomb out and die rather than returning an error indication). \S{utils-index234} \cw{index234()} \c void *index234(tree234 *t, int index); Returns a pointer to the \c{index}th element of the tree, or \cw{NULL} if \c{index} is out of range. Elements of the tree are numbered from zero. \S{utils-find234} \cw{find234()} \c void *find234(tree234 *t, void *e, cmpfn234 cmp); Searches for an element comparing equal to \c{e} in a sorted tree. If \c{cmp} is \cw{NULL}, the tree's ordinary comparison function will be used to perform the search. However, sometimes you don't want that; suppose, for example, each of your elements is a big structure containing a \c{char *} name field, and you want to find the element with a given name. You \e{could} achieve this by constructing a fake element structure, setting its name field appropriately, and passing it to \cw{find234()}, but you might find it more convenient to pass \e{just} a name string to \cw{find234()}, supplying an alternative comparison function which expects one of its arguments to be a bare name and the other to be a large structure containing a name field. Therefore, if \c{cmp} is not \cw{NULL}, then it will be used to compare \c{e} to elements of the tree. The first argument passed to \c{cmp} will always be \c{e}; the second will be an element of the tree. (See \k{utils-newtree234} for the definition of the \c{cmpfn234} function pointer type.) The returned value is the element found, or \cw{NULL} if the search is unsuccessful. \S{utils-findrel234} \cw{findrel234()} \c void *findrel234(tree234 *t, void *e, cmpfn234 cmp, int relation); This function is like \cw{find234()}, but has the additional ability to do a \e{relative} search. The additional parameter \c{relation} can be one of the following values: \dt \cw{REL234_EQ} \dd Find only an element that compares equal to \c{e}. This is exactly the behaviour of \cw{find234()}. \dt \cw{REL234_LT} \dd Find the greatest element that compares strictly less than \c{e}. \c{e} may be \cw{NULL}, in which case it finds the greatest element in the whole tree (which could also be done by \cw{index234(t, count234(t)-1)}). \dt \cw{REL234_LE} \dd Find the greatest element that compares less than or equal to \c{e}. (That is, find an element that compares equal to \c{e} if possible, but failing that settle for something just less than it.) \dt \cw{REL234_GT} \dd Find the smallest element that compares strictly greater than \c{e}. \c{e} may be \cw{NULL}, in which case it finds the smallest element in the whole tree (which could also be done by \cw{index234(t, 0)}). \dt \cw{REL234_GE} \dd Find the smallest element that compares greater than or equal to \c{e}. (That is, find an element that compares equal to \c{e} if possible, but failing that settle for something just bigger than it.) Return value, as before, is the element found or \cw{NULL} if no element satisfied the search criterion. \S{utils-findpos234} \cw{findpos234()} \c void *findpos234(tree234 *t, void *e, cmpfn234 cmp, int *index); This function is like \cw{find234()}, but has the additional feature of returning the index of the element found in the tree; that index is written to \c{*index} in the event of a successful search (a non-\cw{NULL} return value). \c{index} may be \cw{NULL}, in which case this function behaves exactly like \cw{find234()}. \S{utils-findrelpos234} \cw{findrelpos234()} \c void *findrelpos234(tree234 *t, void *e, cmpfn234 cmp, int relation, \c int *index); This function combines all the features of \cw{findrel234()} and \cw{findpos234()}. \S{utils-del234} \cw{del234()} \c void *del234(tree234 *t, void *e); Finds an element comparing equal to \c{e} in the tree, deletes it, and returns it. The input tree must be sorted. The element found might be \c{e} itself, or might merely compare equal to it. Return value is \cw{NULL} if no such element is found. \S{utils-delpos234} \cw{delpos234()} \c void *delpos234(tree234 *t, int index); Deletes the element at position \c{index} in the tree, and returns it. Return value is \cw{NULL} if the index is out of range. \S{utils-count234} \cw{count234()} \c int count234(tree234 *t); Returns the number of elements currently in the tree. \S{utils-splitpos234} \cw{splitpos234()} \c tree234 *splitpos234(tree234 *t, int index, bool before); Splits the input tree into two pieces at a given position, and creates a new tree containing all the elements on one side of that position. If \c{before} is \cw{true}, then all the items at or after position \c{index} are left in the input tree, and the items before that point are returned in the new tree. Otherwise, the reverse happens: all the items at or after \c{index} are moved into the new tree, and those before that point are left in the old one. If \c{index} is equal to 0 or to the number of elements in the input tree, then one of the two trees will end up empty (and this is not an error condition). If \c{index} is further out of range in either direction, the operation will fail completely and return \cw{NULL}. This operation completes in \cw{O(log N)} time, no matter how large the tree or how balanced or unbalanced the split. \S{utils-split234} \cw{split234()} \c tree234 *split234(tree234 *t, void *e, cmpfn234 cmp, int rel); Splits a sorted tree according to its sort order. \c{rel} can be any of the relation constants described in \k{utils-findrel234}, \e{except} for \cw{REL234_EQ}. All the elements having that relation to \c{e} will be transferred into the new tree; the rest will be left in the old one. The parameter \c{cmp} has the same semantics as it does in \cw{find234()}: if it is not \cw{NULL}, it will be used in place of the tree's own comparison function when comparing elements to \c{e}, in such a way that \c{e} itself is always the first of its two operands. Again, this operation completes in \cw{O(log N)} time, no matter how large the tree or how balanced or unbalanced the split. \S{utils-join234} \cw{join234()} \c tree234 *join234(tree234 *t1, tree234 *t2); Joins two trees together by concatenating the lists they represent. All the elements of \c{t2} are moved into \c{t1}, in such a way that they appear \e{after} the elements of \c{t1}. The tree \c{t2} is freed; the return value is \c{t1}. If you apply this function to a sorted tree and it violates the sort order (i.e. the smallest element in \c{t2} is smaller than or equal to the largest element in \c{t1}), the operation will fail and return \cw{NULL}. This operation completes in \cw{O(log N)} time, no matter how large the trees being joined together. \S{utils-join234r} \cw{join234r()} \c tree234 *join234r(tree234 *t1, tree234 *t2); Joins two trees together in exactly the same way as \cw{join234()}, but this time the combined tree is returned in \c{t2}, and \c{t1} is destroyed. The elements in \c{t1} still appear before those in \c{t2}. Again, this operation completes in \cw{O(log N)} time, no matter how large the trees being joined together. \S{utils-copytree234} \cw{copytree234()} \c tree234 *copytree234(tree234 *t, copyfn234 copyfn, \c void *copyfnstate); Makes a copy of an entire tree. If \c{copyfn} is \cw{NULL}, the tree will be copied but the elements will not be; i.e. the new tree will contain pointers to exactly the same physical elements as the old one. If you want to copy each actual element during the operation, you can instead pass a function in \c{copyfn} which makes a copy of each element. That function has the prototype \c typedef void *(*copyfn234)(void *state, void *element); and every time it is called, the \c{state} parameter will be set to the value you passed in as \c{copyfnstate}. \H{utils-dsf} Disjoint set forests This section describes a set of functions implementing the data structure variously known as \q{union-find} or \q{Tarjan's disjoint set forest}. In this code base, it's universally abbreviated as a \q{dsf}. A dsf represents a collection of elements partitioned into \q{equivalence classes}, in circumstances where equivalences are added incrementally. That is, all elements start off considered to be different, and you gradually declare more and more of them to be equal via the \cw{dsf_merge()} operation, which says that two particular elements should be regarded as equal from now on. For example, if I start off with A,B,U,V all distinct, and I merge A with B and merge U with V, then the structure will tell me that A and U are not equivalent. But if I then merge B with V, then after that, the structure will tell me that A and U \e{are} equivalent, by following the transitive chain of equivalences it knows about. The dsf data structure is therefore ideal for tracking incremental connectivity in an undirected graph (again, \q{incremental} meaning that you only ever add edges, never delete them), and other applications in which you gradually acquire knowledge you didn't previously have about what things are the same as each other. It's used extensively in puzzle solver and generator algorithms, and sometimes during gameplay as well. The time complexity of dsf operations is not \e{quite} constant time, in theory, but it's so close to it as to make no difference in practice. In particular, any time a dsf has to do non-trivial work, it updates the structure so that that work won't be needed a second time. Use dsf operations without worrying about how long they take! These functions also support an \q{extended} version of a dsf (spelled \q{edsf}), in which each equivalence class is itself partitioned into two sub-classes. When you merge two elements, you say whether they're in the same class or in opposite classes; when you test equivalence, you can find out whether the two elements you're asking about are in the same or opposite classes. For example, in a puzzle containing black and white squares, you might use an edsf to track the solver's knowledge about whether each pair of squares were (a) the same colour; (b) opposite colours; (c) currently not known to be related. As well as querying whether two elements are equivalent, this dsf implementation also allows you to ask for the number of elements in a given equivalence class, and the smallest element in the class. (The latter is used, for example, to decide which square to print the clue in each region of a Keen puzzle.) \S{utils-dsf-new} \cw{snew_dsf()} \c int *snew_dsf(int size); Allocates space for a dsf describing \c{size} elements, and initialises it so that every element is in an equivalence class by itself. The elements described by the dsf are represented by the integers from \cw{0} to \cw{size-1} inclusive. The returned memory is a single allocation, so you can free it easily using \cw{sfree()}. Dsfs and edsfs are represented in the same way, so this function can be used to allocate either kind. \S{utils-dsf-init} \cw{dsf_init()} \c void dsf_init(int *dsf, int size); Reinitialises an existing dsf to the state in which all elements are distinct, without having to free and reallocate it. \S{utils-dsf-merge} \cw{dsf_merge()} \c void dsf_merge(int *dsf, int v1, int v2); Updates a dsf so that elements \c{v1} and \c{v2} will now be considered to be in the same equivalence class. If they were already in the same class, this function will safely do nothing. \S{utils-dsf-canonify} \cw{dsf_canonify()} \c int dsf_canonify(int *dsf, int val); Returns the \q{canonical} element of the equivalence class in the dsf containing \c{val}. This will be some element of the same equivalence class. So in order to determine whether two elements are in the same equivalence class, you can call \cw{dsf_canonify} on both of them, and compare the results. Canonical elements don't necessarily stay the same if the dsf is mutated via \c{dsf_merge}. But between two calls to \c{dsf_merge}, they stay the same. In this implementation, the canonical element is always the element with smallest index in the equivalence class. \S{utils-dsf-size} \cw{dsf_size()} \c int dsf_size(int *dsf, int val); Returns the number of elements currently in the equivalence class containing \c{val}. \c{val} itself counts, so in a newly created dsf, the return value will be 1. \S{utils-edsf-merge} \cw{edsf_merge()} \c void edsf_merge(int *dsf, int v1, int v2, bool inverse); Updates an edsf so that elements \c{v1} and \c{v2} are in the same equivalence class. If \c{inverse} is \cw{false}, they will be regarded as also being in the same subclass of that class; if \c{inverse} is \cw{true} then they will be regarded as being in opposite subclasses. If \c{v1} and \c{v2} were already in the same equivalence class, then the new value of \c{inverse} will be checked against what the edsf previously believed, and an assertion failure will occur if you contradict that. For example, if you start from a blank edsf and do this: \c edsf_merge(dsf, 0, 1, false); \c edsf_merge(dsf, 1, 2, true); then it will create a dsf in which elements 0,1,2 are all in the same class, with one subclasses containing 0,1 and the other containing 2. And then this call will do nothing, because it agrees with what the edsf already knew: \c edsf_merge(dsf, 0, 2, true); But this call will fail an assertion: \c edsf_merge(dsf, 0, 2, false); \S{utils-edsf-canonify} \cw{edsf_canonify()} \c int edsf_canonify(int *dsf, int val, bool *inverse); Like \c{dsf_canonify()}, this returns the canonical element of the equivalence class of an edsf containing \c{val}. It also fills in \c{*inverse} with a flag indicating whether \c{val} and the canonical element are in opposite subclasses: \cw{true} if they are in opposite subclasses, or \cw{false} if they're in the same subclass. So if you want to know the relationship between \c{v1} and \c{v2}, you can do this: \c bool inv1, inv2; \c int canon1 = edsf_canonify(dsf, v1, &inv1); \c int canon2 = edsf_canonify(dsf, v2, &inv2); \c if (canon1 != canon2) { \c // v1 and v2 have no known relation \c } else if (inv1 == inv2) { \c // v1 and v2 are in the same subclass of the same class \c } else { \c // v1 and v2 are in opposite subclasses of the same class \c } \H{utils-tdq} To-do queues This section describes a set of functions implementing a \q{to-do queue}, a simple de-duplicating to-do list mechanism. The code calls this a \q{tdq}. A tdq can store integers up to a given size (specified at creation time). But it can't store the same integer more than once. So you can quickly \e{make sure} an integer is in the queue (which will do nothing if it's already there), and you can quickly pop an integer from the queue and return it, both in constant time. The idea is that you might use this in a game solver, in the kind of game where updating your knowledge about one square of a grid means there's a specific other set of squares (such as its neighbours) where it's now worth attempting further deductions. So you keep a tdq of all the grid squares you plan to look at next, and every time you make a deduction in one square, you add the neighbouring squares to the tdq to make sure they get looked at again after that. In solvers where deductions are mostly localised, this avoids the slowdown of having to find the next thing to do every time by looping over the whole grid: instead, you can keep checking the tdq for \e{specific} squares to look at, until you run out. However, it's common to have games in which \e{most} deductions are localised, but not all. In that situation, when your tdq is empty, you can re-fill it with every square in the grid using \cw{tdq_fill()}, which will force an iteration over everything again. And then if the tdq becomes empty \e{again} without you having made any progress, give up. \S{utils-tdq-new} \cw{tdq_new()} \c tdq *tdq_new(int n); Allocates space for a tdq that tracks items from \cw{0} to \cw{size-1} inclusive. \S{utils-tdq-free} \cw{tdq_free()} \c void tdq_free(tdq *tdq); Frees a tdq. \S{utils-tdq-add} \cw{tdq_add()} \c void tdq_add(tdq *tdq, int k); Adds the value \c{k} to a tdq. If \c{k} was already in the to-do list, does nothing. \S{utils-tdq-remove} \cw{tdq_remove()} \c int tdq_remove(tdq *tdq); Removes one item from the tdq, and returns it. If the tdq is empty, returns \cw{-1}. \S{utils-tdq-fill} \cw{tdq_fill()} \c void tdq_fill(tdq *tdq); Fills a tdq with every element it can possibly keep track of. \H{utils-findloop} Finding loops in graphs and grids Many puzzles played on grids or graphs have a common gameplay element of connecting things together into paths in such a way that you need to avoid making loops (or, perhaps, making the \e{wrong} kind of loop). Just determining \e{whether} a loop exists in a graph is easy, using a dsf tracking connectivity between the vertices. Simply iterate over each edge of the graph, merging the two vertices at each end of the edge \dash but before you do that, check whether those vertices are \e{already} known to be connected to each other, and if they are, then the new edge is about to complete a loop. But if you also want to identify \e{exactly} the set of edges that are part of any loop, e.g. to highlight the whole loop red during gameplay, then that's a harder problem. This API is provided here for all puzzles to use for that purpose. \S{utils-findloop-new-state} \cw{findloop_new_state()} \c struct findloopstate *findloop_new_state(int nvertices); Allocates a new state structure for the findloop algorithm, capable of handling a graph with up to \c{nvertices} vertices. The vertices will be represented by integers between \c{0} and \c{nvertices-1} inclusive. \S{utils-findloop-free-state} \cw{findloop_free_state()} \c void findloop_free_state(struct findloopstate *state); Frees a state structure allocated by \cw{findloop_new_state()}. \S{utils-findloop-run} \cw{findloop_run()} \c bool findloop_run(struct findloopstate *state, int nvertices, \c neighbour_fn_t neighbour, void *ctx); Runs the loop-finding algorithm, which will explore the graph and identify whether each edge is or is not part of any loop. The algorithm will call the provided function \c{neighbour} to list the neighbouring vertices of each vertex. It should have this prototype: \c int neighbour(int vertex, void *ctx); In this callback, \c{vertex} will be the index of a vertex when the algorithm \e{first} calls it for a given vertex. The function should return the index of one of that vertex's neighbours, or a negative number if there are none. If the function returned a vertex, the algorithm will then call \c{neighbour} again with a \e{negative} number as the \c{vertex} parameter, which means \q{please give me another neighbour of the same vertex as last time}. Again, the function should return a vertex index, or a negative number to indicate that there are no more vertices. The \c{ctx} parameter passed to \cw{findloop_run()} is passed on unchanged to \c{neighbour}, so you can point that at your game state or solver state or whatever. The return value is \cw{true} if at least one loop exists in the graph, and \cw{false} if no loop exists. Also, the algorithm state will have been filled in with information that the following query functions can use to ask about individual graph edges. \S{utils-findloop-is-loop-edge} \cw{findloop_is_loop_edge()} \c bool findloop_is_loop_edge(struct findloopstate *state, \c int u, int v); Queries whether the graph edge between vertices \c{u} and \c{v} is part of a loop. If so, the return value is \cw{true}, otherwise \cw{false}. \S{utils-findloop-is-bridge} \cw{findloop_is_bridge()} \c bool findloop_is_bridge(struct findloopstate *pv, \c int u, int v, int *u_vertices, int *v_vertices); Queries whether the graph edge between vertices \c{u} and \c{v} is a \q{bridge}, i.e. an edge which would break the graph into (more) disconnected components if it were removed. This is the exact inverse of the \q{loop edge} criterion: a vertex returns \cw{true} from \cw{findloop_is_loop_edge()} if and only if it returns \cw{false} from \cw{findloop_is_bridge()}, and vice versa. However, \cw{findloop_is_bridge()} returns more information. If it returns \cw{true}, then it also fills in \c{*u_vertices} and \c{*v_vertices} with the number of vertices connected to the \c{u} and \c{v} sides of the bridge respectively. For example, if you have three vertices A,B,C all connected to each other, and four vertices U,V,W,X all connected to each other, and a single edge between A and V, then calling \cw{findloop_is_bridge()} on the pair A,V will return true (removing that edge would separate the two sets from each other), and will report that there are three vertices on the A side and four on the V side. \H{utils-combi} Choosing r things out of n This section describes a small API for iterating over all combinations of r things out of n. For example, if you asked for all combinations of 3 things out of 5, you'd get back the sets \{0,1,2\}, \{0,1,3\}, \{0,1,4\}, \{0,2,3\}, \{0,2,4\}, \{0,3,4\}, \{1,2,3\}, \{1,2,4\}, \{1,3,4\}, and \{2,3,4\}. These functions use a structure called a \c{combi_ctx}, which contains an element \c{int *a} holding each returned combination, plus other fields for implementation use only. \S{utils-combi-new} \cw{new_combi()} \c combi_ctx *new_combi(int r, int n); Allocates a new \c{combi_ctx} structure for enumerating r things out of n. \S{utils-combi-free} \cw{free_combi()} \c void free_combi(combi_ctx *combi); Frees a \c{combi_ctx} structure. \S{utils-combi-reset} \cw{reset_combi()} \c void reset_combi(combi_ctx *combi); Resets an existing \c{combi_ctx} structure to the start of its iteration \S{utils-combi-next} \cw{next_combi()} \c combi_ctx *next_combi(combi_ctx *combi); Requests a combination from a \c{combi_ctx}. If there are none left to return, the return value is \cw{NULL}. Otherwise, it returns the input structure \c{combi}, indicating that it has filled in \cw{combi->a[0]}, \cw{combi->a[1]}, ..., \cw{combi->a[r-1]} with an increasing sequence of distinct integers from \cw{0} to \cw{n-1} inclusive. \H{utils-misc} Miscellaneous utility functions and macros This section contains all the utility functions which didn't sensibly fit anywhere else. \S{utils-maxmin} \cw{max()} and \cw{min()} The main Puzzles header file defines the pretty standard macros \cw{max()} and \cw{min()}, each of which is given two arguments and returns the one which compares greater or less respectively. These macros may evaluate their arguments multiple times. Avoid side effects. \S{utils-max-digits} \cw{MAX_DIGITS()} The \cw{MAX_DIGITS()} macro, defined in the main Puzzles header file, takes a type (or a variable of that type) and expands to an integer constant representing a reasonable upper bound on the number of characters that a number of that type could expand to when formatted as a decimal number using the \c{%u} or \c{%d} format of \cw{printf()}. This is useful for allocating a fixed-size buffer that's guaranteed to be big enough to \cw{sprintf()} a value into. Don't forget to add one for the trailing \cw{'\\0'}! \S{utils-pi} \cw{PI} The main Puzzles header file defines a macro \cw{PI} which expands to a floating-point constant representing pi. (I've never understood why ANSI's \cw{<math.h>} doesn't define this. It'd be so useful!) \S{utils-obfuscate-bitmap} \cw{obfuscate_bitmap()} \c void obfuscate_bitmap(unsigned char *bmp, int bits, bool decode); This function obscures the contents of a piece of data, by cryptographic methods. It is useful for games of hidden information (such as Mines, Guess or Black Box), in which the game ID theoretically reveals all the information the player is supposed to be trying to guess. So in order that players should be able to send game IDs to one another without accidentally spoiling the resulting game by looking at them, these games obfuscate their game IDs using this function. Although the obfuscation function is cryptographic, it cannot properly be called encryption because it has no key. Therefore, anybody motivated enough can re-implement it, or hack it out of the Puzzles source, and strip the obfuscation off one of these game IDs to see what lies beneath. (Indeed, they could usually do it much more easily than that, by entering the game ID into their own copy of the puzzle and hitting Solve.) The aim is not to protect against a determined attacker; the aim is simply to protect people who wanted to play the game honestly from \e{accidentally} spoiling their own fun. The input argument \c{bmp} points at a piece of memory to be obfuscated. \c{bits} gives the length of the data. Note that that length is in \e{bits} rather than bytes: if you ask for obfuscation of a partial number of bytes, then you will get it. Bytes are considered to be used from the top down: thus, for example, setting \c{bits} to 10 will cover the whole of \cw{bmp[0]} and the \e{top two} bits of \cw{bmp[1]}. The remainder of a partially used byte is undefined (i.e. it may be corrupted by the function). The parameter \c{decode} is \cw{false} for an encoding operation, and \cw{true} for a decoding operation. Each is the inverse of the other. (There's no particular reason you shouldn't obfuscate by decoding and restore cleartext by encoding, if you really wanted to; it should still work.) The input bitmap is processed in place. \S{utils-bin2hex} \cw{bin2hex()} \c char *bin2hex(const unsigned char *in, int inlen); This function takes an input byte array and converts it into an ASCII string encoding those bytes in (lower-case) hex. It returns a dynamically allocated string containing that encoding. This function is useful for encoding the result of \cw{obfuscate_bitmap()} in printable ASCII for use in game IDs. \S{utils-hex2bin} \cw{hex2bin()} \c unsigned char *hex2bin(const char *in, int outlen); This function takes an ASCII string containing hex digits, and converts it back into a byte array of length \c{outlen}. If there aren't enough hex digits in the string, the contents of the resulting array will be undefined. This function is the inverse of \cw{bin2hex()}. \S{utils-fgetline} \cw{fgetline()} \c char *fgetline(FILE *fp); This function reads a single line of text from a standard C input stream, and returns it as a dynamically allocated string. The returned string still has a newline on the end. \S{utils-arraysort} \cw{arraysort()} Sorts an array, with slightly more flexibility than the standard C \cw{qsort()}. This function is really implemented as a macro, so it doesn't have a prototype as such. But you could imagine it having a prototype like this: \c void arraysort(element_t *array, size_t nmemb, \c arraysort_cmpfn_t cmp, void *ctx); in which \c{element_t} is an unspecified type. (Really, there's an underlying function that takes an extra parameter giving the size of each array element. But callers are encouraged to use this macro version, which fills that in automatically using \c{sizeof}.) This function behaves essentially like \cw{qsort()}: it expects \c{array} to point to an array of \c{nmemb} elements, and it will sort them in place into the order specified by the comparison function \c{cmp}. The comparison function should have this prototype: \c int cmp(const void *a, const void *b, void *ctx); in which \c{a} and \c{b} point at the two elements to be compared, and the return value is negative if \cw{a<b} (that is, \c{a} should appear before \c{b} in the output array), positive if \cw{a>b}, or zero if \c{a=b}. The \c{ctx} parameter to \cw{arraysort()} is passed directly to the comparison function. This is the feature that makes \cw{arraysort()} more flexible than standard \cw{qsort()}: it lets you vary the sorting criterion in a dynamic manner without having to write global variables in the caller for the compare function to read. \S{utils-colour-mix} \cw{colour_mix()} \c void colour_mix(const float src1[3], const float src2[3], float p, \c float dst[3]); This function mixes the colours \c{src1} and \c{src2} in specified proportions, producing \c{dst}. \c{p} is the proportion of \c{src2} in the result. So if \c{p} is \cw{1.0}, \cw{dst} will be the same as \c{src2}. If \c{p} is \cw{0.0}, \cw{dst} will be the same as \c{src1}. And if \c{p} is somewhere in between, so will \c{dst} be. \c{p} is not restricted to the range \cw{0.0} to \cw{1.0}. Values outside that range will produce extrapolated colours, which may be useful for some purposes, but may also produce impossible colours. \S{utils-game-mkhighlight} \cw{game_mkhighlight()} \c void game_mkhighlight(frontend *fe, float *ret, \c int background, int highlight, int lowlight); It's reasonably common for a puzzle game's graphics to use highlights and lowlights to indicate \q{raised} or \q{lowered} sections. Fifteen, Sixteen and Twiddle are good examples of this. Puzzles using this graphical style are running a risk if they just use whatever background colour is supplied to them by the front end, because that background colour might be too light or dark to see any highlights on at all. (In particular, it's not unheard of for the front end to specify a default background colour of white.) Therefore, such puzzles can call this utility function from their \cw{colours()} routine (\k{backend-colours}). You pass it your front end handle, a pointer to the start of your return array, and three colour indices. It will: \b call \cw{frontend_default_colour()} (\k{frontend-default-colour}) to fetch the front end's default background colour \b alter the brightness of that colour if it's unsuitable \b define brighter and darker variants of the colour to be used as highlights and lowlights \b write those results into the relevant positions in the \c{ret} array. Thus, \cw{ret[background*3]} to \cw{ret[background*3+2]} will be set to RGB values defining a sensible background colour, and similary \c{highlight} and \c{lowlight} will be set to sensible colours. Either \c{highlight} or \c{lowlight} may be passed in as \cw{-1} to indicate that the back-end does not require a highlight or lowlight colour, respectively. \S{utils-game-mkhighlight-specific} \cw{game_mkhighlight_specific()} \c void game_mkhighlight_specific(frontend *fe, float *ret, \c int background, int highlight, int lowlight); This function behaves exactly like \cw{game_mkhighlight()}, except that it expects the background colour to have been filled in \e{already} in the elements \cw{ret[background*3]} to \cw{ret[background*3+2]}. It will fill in the other two colours as brighter and darker versions of that. This is useful if you want to show relief sections of a puzzle in more than one base colour. \S{utils-button2label} \cw{button2label()} \c char *button2label(int button); This function generates a descriptive text label for \cw{button}, which should be a button code that can be passed to the midend. For example, calling this function with \cw{CURSOR_UP} will result in the string \cw{"Up"}. This function should only be called when the \cw{key_label} item returned by a backend's \cw{request_keys()} (\k{backend-request-keys}) function has its \cw{label} field set to \cw{NULL}; in this case, the corresponding \cw{button} field can be passed to this function to obtain an appropriate label. If, however, the field is not \cw{NULL}, this function should not be called with the corresponding \cw{button} field. The returned string is dynamically allocated and should be \cw{sfree}'d by the caller. \S{utils-move-cursor} \cw{move_cursor()} \c void move_cursor(int button, int *x, int *y, int w, int h, \c bool wrap); This function can be called by \cw{interpret_move()} to implement the default keyboard API for moving a cursor around a grid. \c{button} is the same value passed in to \cw{interpret_move()}. If it's not any of \cw{CURSOR_UP}, \cw{CURSOR_DOWN}, \cw{CURSOR_LEFT} or \cw{CURSOR_RIGHT}, the function will do nothing. \c{x} and \c{y} point to two integers which on input give the current location of a cursor in a square grid. \c{w} and \c{h} give the dimensions of the grid. On return, \c{x} and \c{y} are updated to give the cursor's new position according to which arrow key was pressed. This function assumes that the grid coordinates run from \cw{0} to \cw{w-1} inclusive (left to right), and from \cw{0} to \cw{h-1} inclusive (top to bottom). If \c{wrap} is \cw{true}, then trying to move the cursor off any edge of the grid will result in it wrapping round to the corresponding square on the opposite edge. If \c{wrap} is \cw{false}, such a move will have no effect. \S{utils-divvy-rectangle} \cw{divvy_rectangle()} \c int *divvy_rectangle(int w, int h, int k, random_state *rs); Invents a random division of a rectangle into same-sized polyominoes, such as is found in the block layout of a Solo puzzle in jigsaw mode, or the solution to a Palisade puzzle. \c{w} and \c{h} are the dimensions of the rectangle. \c{k} is the size of polyomino desired. It must be a factor of \c{w*h}. \c{rs} is a \cw{random_state} used to supply the random numbers to select a random division of the rectangle. The return value is a dsf (see \k{utils-dsf}) whose equivalence classes correspond to the polyominoes that the rectangle is divided into. The indices of the dsf are of the form \c{y*w+x}, for the cell with coordinates \cw{x,y}. \S{utils-domino-layout} \cw{domino_layout()} \c int *domino_layout(int w, int h, random_state *rs); Invents a random tiling of a rectangle with dominoes. \c{w} and \c{h} are the dimensions of the rectangle. If they are both odd, then one square will be left untiled. \c{rs} is a \cw{random_state} used to supply the random numbers to select a random division of the rectangle. The return value is an array in which element \c{y*w+x} represents the cell with coordinates \cw{x,y}. Each element of the array gives the index (in the same representation) of the other end of its domino. If there's a left-over square, then that element contains its own index. \S{utils-domino-layout-prealloc} \cw{domino_layout_prealloc()} \c void domino_layout_prealloc(int w, int h, random_state *rs, \c int *grid, int *grid2, int *list); Just like \cw{domino_layout()}, but does no memory allocation. You can use this to save allocator overhead if you expect to need to generate many domino tilings of the same grid. \c{grid} and \c{grid2} should each have space for \cw{w*h} ints. \c{list} should have space for \c{2*w*h} ints. The returned array is delivered in \c{grid}. \C{writing} How to write a new puzzle This chapter gives a guide to how to actually write a new puzzle: where to start, what to do first, how to solve common problems. The previous chapters have been largely composed of facts. This one is mostly advice. \H{writing-editorial} Choosing a puzzle Before you start writing a puzzle, you have to choose one. Your taste in puzzle games is up to you, of course; and, in fact, you're probably reading this guide because you've \e{already} thought of a game you want to write. But if you want to get it accepted into the official Puzzles distribution, then there's a criterion it has to meet. The current Puzzles editorial policy is that all games should be \e{fair}. A fair game is one which a player can only fail to complete through demonstrable lack of skill \dash that is, such that a better player presented with the same game state would have \e{known} to do something different. For a start, that means every game presented to the user must have \e{at least one solution}. Giving the unsuspecting user a puzzle which is actually impossible is not acceptable. (An exception to this: if the user has selected some non-default option which is clearly labelled as potentially unfair, \e{then} you're allowed to generate possibly insoluble puzzles, because the user isn't unsuspecting any more. Same Game and Mines both have options of this type.) Secondly, if the game includes hidden information, then it must be possible to deduce a correct move at every stage from the currently available information. It's not enough that there should exist some sequence of moves which will get from the start state to the solved state, if the player doesn't necessarily have enough information to \e{find} that solution. For example, in the card solitaire game Klondike, it's possible to reach a dead end because you had an arbitrary choice to make on no information, and made it the wrong way, which violates the fairness criterion, because a better player couldn't have known they needed to make the other choice. (Of course, games in this collection always have an Undo function, so if you did take the wrong route through a Klondike game, you could use Undo to back up and try a different choice. This doesn't count. In a fair game, you should be able to determine a correct move from the information visible \e{now}, without having to make moves to get more information that you can then back up and use.) Sometimes you can adjust the rules of an unfair puzzle to make it meet this definition of fairness. For example, more than one implementation of solitaire-style games (including card solitaires and Mahjong Solitaire) include a UI action to shuffle the remaining cards or tiles without changing their position; this action might be available at any time with a time or points penalty, or it might be illegal to use unless you have no other possible move. Adding an option like this would make a game \e{technically} fair, but it's better to avoid even that if you can. Providing a \e{unique} solution is a little more negotiable; it depends on the puzzle. Solo would have been of unacceptably low quality if it didn't always have a unique solution, whereas Twiddle inherently has multiple solutions by its very nature and it would have been meaningless to even \e{suggest} making it uniquely soluble. Somewhere in between, Flip could reasonably be made to have unique solutions (by enforcing a zero-dimension kernel in every generated matrix) but it doesn't seem like a serious quality problem that it doesn't. Of course, you don't \e{have} to care about all this. There's nothing stopping you implementing any puzzle you want to if you're happy to maintain your puzzle yourself, distribute it from your own web site, fork the Puzzles code completely, or anything like that. It's free software; you can do what you like with it. But any game that you want to be accepted into \e{my} Puzzles code base has to satisfy the fairness criterion, which means all randomly generated puzzles must have a solution (unless the user has deliberately chosen otherwise) and it must be possible \e{in theory} to find that solution without having to guess. \H{writing-gs} Getting started The simplest way to start writing a new puzzle is to copy \c{nullgame.c}. This is a template puzzle source file which does almost nothing, but which contains all the back end function prototypes and declares the back end data structure correctly. It is built every time the rest of Puzzles is built, to ensure that it doesn't get out of sync with the code and remains buildable. So start by copying \c{nullgame.c} into your new source file. Then you'll gradually add functionality until the very boring Null Game turns into your real game. Next you'll need to add your puzzle to the build scripts, in order to compile it conveniently. Puzzles is a CMake project, so you do this by adding a \cw{puzzle()} statement to CMakeLists.txt. Look at the existing ones to see what those look like, and add one that looks similar. Once your source file is building, you can move on to the fun bit. \S{writing-generation} Puzzle generation Randomly generating instances of your puzzle is almost certain to be the most difficult part of the code, and also the task with the highest chance of turning out to be completely infeasible. Therefore I strongly recommend doing it \e{first}, so that if it all goes horribly wrong you haven't wasted any more time than you absolutely had to. What I usually do is to take an unmodified \c{nullgame.c}, and start adding code to \cw{new_game_desc()} which tries to generate a puzzle instance and print it out using \cw{printf()}. Once that's working, \e{then} I start connecting it up to the return value of \cw{new_game_desc()}, populating other structures like \c{game_params}, and generally writing the rest of the source file. There are many ways to generate a puzzle which is known to be soluble. In this section I list all the methods I currently know of, in case any of them can be applied to your puzzle. (Not all of these methods will work, or in some cases even make sense, for all puzzles.) Some puzzles are mathematically tractable, meaning you can work out in advance which instances are soluble. Sixteen, for example, has a parity constraint in some settings which renders exactly half the game space unreachable, but it can be mathematically proved that any position not in that half \e{is} reachable. Therefore, Sixteen's grid generation simply consists of selecting at random from a well defined subset of the game space. Cube in its default state is even easier: \e{every} possible arrangement of the blue squares and the cube's starting position is soluble! Another option is to redefine what you mean by \q{soluble}. Black Box takes this approach. There are layouts of balls in the box which are completely indistinguishable from one another no matter how many beams you fire into the box from which angles, which would normally be grounds for declaring those layouts unfair; but fortunately, detecting that indistinguishability is computationally easy. So Black Box doesn't demand that your ball placements match its own; it merely demands that your ball placements be \e{indistinguishable} from the ones it was thinking of. If you have an ambiguous puzzle, then any of the possible answers is considered to be a solution. Having redefined the rules in that way, any puzzle is soluble again. Those are the simple techniques. If they don't work, you have to get cleverer. One way to generate a soluble puzzle is to start from the solved state and make inverse moves until you reach a starting state. Then you know there's a solution, because you can just list the inverse moves you made and make them in the opposite order to return to the solved state. This method can be simple and effective for puzzles where you get to decide what's a starting state and what's not. In Pegs, for example, the generator begins with one peg in the centre of the board and makes inverse moves until it gets bored; in this puzzle, valid inverse moves are easy to detect, and \e{any} state that's reachable from the solved state by inverse moves is a reasonable starting position. So Pegs just continues making inverse moves until the board satisfies some criteria about extent and density, and then stops and declares itself done. For other puzzles, it can be a lot more difficult. Same Game uses this strategy too, and it's lucky to get away with it at all: valid inverse moves aren't easy to find (because although it's easy to insert additional squares in a Same Game position, it's difficult to arrange that \e{after} the insertion they aren't adjacent to any other squares of the same colour), so you're constantly at risk of running out of options and having to backtrack or start again. Also, Same Game grids never start off half-empty, which means you can't just stop when you run out of moves \dash you have to find a way to fill the grid up \e{completely}. The other way to generate a puzzle that's soluble is to start from the other end, and actually write a \e{solver}. This tends to ensure that a puzzle has a \e{unique} solution over and above having a solution at all, so it's a good technique to apply to puzzles for which that's important. One theoretical drawback of generating soluble puzzles by using a solver is that your puzzles are restricted in difficulty to those which the solver can handle. (Most solvers are not fully general: many sets of puzzle rules are NP-complete or otherwise nasty, so most solvers can only handle a subset of the theoretically soluble puzzles.) It's been my experience in practice, however, that this usually isn't a problem; computers are good at very different things from humans, and what the computer thinks is nice and easy might still be pleasantly challenging for a human. For example, when solving Dominosa puzzles I frequently find myself using a variety of reasoning techniques that my solver doesn't know about; in principle, therefore, I should be able to solve the puzzle using only those techniques it \e{does} know about, but this would involve repeatedly searching the entire grid for the one simple deduction I can make. Computers are good at this sort of exhaustive search, but it's been my experience that human solvers prefer to do more complex deductions than to spend ages searching for simple ones. So in many cases I don't find my own playing experience to be limited by the restrictions on the solver. (This isn't \e{always} the case. Solo is a counter-example; generating Solo puzzles using a simple solver does lead to qualitatively easier puzzles. Therefore I had to make the Solo solver rather more advanced than most of them.) There are several different ways to apply a solver to the problem of generating a soluble puzzle. I list a few of them below. The simplest approach is brute force: randomly generate a puzzle, use the solver to see if it's soluble, and if not, throw it away and try again until you get lucky. This is often a viable technique if all else fails, but it tends not to scale well: for many puzzle types, the probability of finding a uniquely soluble instance decreases sharply as puzzle size goes up, so this technique might work reasonably fast for small puzzles but take (almost) forever at larger sizes. Still, if there's no other alternative it can be usable: Pattern and Dominosa both use this technique. (However, Dominosa has a means of tweaking the randomly generated grids to increase the \e{probability} of them being soluble, by ruling out one of the most common ambiguous cases. This improved generation speed by over a factor of 10 on the highest preset!) An approach which can be more scalable involves generating a grid and then tweaking it to make it soluble. This is the technique used by Mines and also by Net: first a random puzzle is generated, and then the solver is run to see how far it gets. Sometimes the solver will get stuck; when that happens, examine the area it's having trouble with, and make a small random change in that area to allow it to make more progress. Continue solving (possibly even without restarting the solver), tweaking as necessary, until the solver finishes. Then restart the solver from the beginning to ensure that the tweaks haven't caused new problems in the process of solving old ones (which can sometimes happen). This strategy works well in situations where the usual solver failure mode is to get stuck in an easily localised spot. Thus it works well for Net and Mines, whose most common failure mode tends to be that most of the grid is fine but there are a few widely separated ambiguous sections; but it would work less well for Dominosa, in which the way you get stuck is to have scoured the whole grid and not found anything you can deduce \e{anywhere}. Also, it relies on there being a low probability that tweaking the grid introduces a new problem at the same time as solving the old one; Mines and Net also have the property that most of their deductions are local, so that it's very unlikely for a tweak to affect something half way across the grid from the location where it was applied. In Dominosa, by contrast, a lot of deductions use information about half the grid (\q{out of all the sixes, only one is next to a three}, which can depend on the values of up to 32 of the 56 squares in the default setting!), so this tweaking strategy would be rather less likely to work well. A more specialised strategy is that used in Solo and Slant. These puzzles have the property that they derive their difficulty from not presenting all the available clues. (In Solo's case, if all the possible clues were provided then the puzzle would already be solved; in Slant it would still require user action to fill in the lines, but it would present no challenge at all). Therefore, a simple generation technique is to leave the decision of which clues to provide until the last minute. In other words, first generate a random \e{filled} grid with all possible clues present, and then gradually remove clues for as long as the solver reports that it's still soluble. Unlike the methods described above, this technique \e{cannot} fail \dash once you've got a filled grid, nothing can stop you from being able to convert it into a viable puzzle. However, it wouldn't even be meaningful to apply this technique to (say) Pattern, in which clues can never be left out, so the only way to affect the set of clues is by altering the solution. (Unfortunately, Solo is complicated by the need to provide puzzles at varying difficulty levels. It's easy enough to generate a puzzle of \e{at most} a given level of difficulty; you just have a solver with configurable intelligence, and you set it to a given level and apply the above technique, thus guaranteeing that the resulting grid is solvable by someone with at most that much intelligence. However, generating a puzzle of \e{at least} a given level of difficulty is rather harder; if you go for \e{at most} Intermediate level, you're likely to find that you've accidentally generated a Trivial grid a lot of the time, because removing just one number is sufficient to take the puzzle from Trivial straight to Ambiguous. In that situation Solo has no remaining options but to throw the puzzle away and start again.) A final strategy is to use the solver \e{during} puzzle construction: lay out a bit of the grid, run the solver to see what it allows you to deduce, and then lay out a bit more to allow the solver to make more progress. There are articles on the web that recommend constructing Sudoku puzzles by this method (which is completely the opposite way round to how Solo does it); for Sudoku it has the advantage that you get to specify your clue squares in advance (so you can have them make pretty patterns). Rectangles uses a strategy along these lines. First it generates a grid by placing the actual rectangles; then it has to decide where in each rectangle to place a number. It uses a solver to help it place the numbers in such a way as to ensure a unique solution. It does this by means of running a test solver, but it runs the solver \e{before} it's placed any of the numbers \dash which means the solver must be capable of coping with uncertainty about exactly where the numbers are! It runs the solver as far as it can until it gets stuck; then it narrows down the possible positions of a number in order to allow the solver to make more progress, and so on. Most of the time this process terminates with the grid fully solved, at which point any remaining number-placement decisions can be made at random from the options not so far ruled out. Note that unlike the Net/Mines tweaking strategy described above, this algorithm does not require a checking run after it completes: if it finishes successfully at all, then it has definitely produced a uniquely soluble puzzle. Most of the strategies described above are not 100% reliable. Each one has a failure rate: every so often it has to throw out the whole grid and generate a fresh one from scratch. (Solo's strategy would be the exception, if it weren't for the need to provide configurable difficulty levels.) Occasional failures are not a fundamental problem in this sort of work, however: it's just a question of dividing the grid generation time by the success rate (if it takes 10ms to generate a candidate grid and 1/5 of them work, then it will take 50ms on average to generate a viable one), and seeing whether the expected time taken to \e{successfully} generate a puzzle is unacceptably slow. Dominosa's generator has a very low success rate (about 1 out of 20 candidate grids turn out to be usable, and if you think \e{that's} bad then go and look at the source code and find the comment showing what the figures were before the generation-time tweaks!), but the generator itself is very fast so this doesn't matter. Rectangles has a slower generator, but fails well under 50% of the time. So don't be discouraged if you have an algorithm that doesn't always work: if it \e{nearly} always works, that's probably good enough. The one place where reliability is important is that your algorithm must never produce false positives: it must not claim a puzzle is soluble when it isn't. It can produce false negatives (failing to notice that a puzzle is soluble), and it can fail to generate a puzzle at all, provided it doesn't do either so often as to become slow. One last piece of advice: for grid-based puzzles, when writing and testing your generation algorithm, it's almost always a good idea \e{not} to test it initially on a grid that's square (i.e. \cw{w==h}), because if the grid is square then you won't notice if you mistakenly write \c{h} instead of \c{w} (or vice versa) somewhere in the code. Use a rectangular grid for testing, and any size of grid will be likely to work after that. \S{writing-textformats} Designing textual description formats Another aspect of writing a puzzle which is worth putting some thought into is the design of the various text description formats: the format of the game parameter encoding, the game description encoding, and the move encoding. The first two of these should be reasonably intuitive for a user to type in; so provide some flexibility where possible. Suppose, for example, your parameter format consists of two numbers separated by an \c{x} to specify the grid dimensions (\c{10x10} or \c{20x15}), and then has some suffixes to specify other aspects of the game type. It's almost always a good idea in this situation to arrange that \cw{decode_params()} can handle the suffixes appearing in any order, even if \cw{encode_params()} only ever generates them in one order. These formats will also be expected to be reasonably stable: users will expect to be able to exchange game IDs with other users who aren't running exactly the same version of your game. So make them robust and stable: don't build too many assumptions into the game ID format which will have to be changed every time something subtle changes in the puzzle code. \H{writing-howto} Common how-to questions This section lists some common things people want to do when writing a puzzle, and describes how to achieve them within the Puzzles framework. \S{writing-howto-redraw} Redrawing just the changed parts of the window Redrawing the entire window on every move is wasteful. If the user makes a move changing only one square of a grid, it's better to redraw just that square. (Yes, computers are fast these days, but these puzzles still try to be portable to devices at the less fast end of the spectrum, so it's still worth saving effort where it's easy. On the other hand, some puzzles just \e{can't} do this easily \dash Untangle is an example that really does have no better option than to redraw everything.) For a typical grid-oriented puzzle, a robust way to do this is: \b Invent a data representation that describes everything about the appearance of a grid cell in the puzzle window. \b Have \c{game_drawstate} contain an array of those, describing the current appearance of each cell, as it was last drawn in the window. \b In \cw{redraw()}, loop over each cell deciding what the new appearance should be. If it's not the same as the value stored in \c{game_drawstate}, then redraw that cell, and update the entry in the \c{game_drawstate} array. Where possible, I generally make my data representation an integer full of bit flags, to save space, and to make it easy to compare the old and new versions. If yours needs to be bigger than that, you may have to define a small \cw{struct} and write an equality-checking function. The data representation of the \e{appearance} of a square in \c{game_drawstate} will not generally be identical to the representation of the \e{logical state} of a square in \c{game_state}, because many things contribute to a square's appearance other than its logical state. For example: \b Extra information overlaid on the square by the user interface, such as a keyboard-controlled cursor, or highlighting of squares currently involved in a mouse drag action. \b Error highlights marking violations of the puzzle constraints. \b Visual intrusions into one square because of things in nearby squares. For example, if you draw thick lines along the edges between grid squares, then the corners of those lines will be visible in logically unrelated squares. An entry in the \c{game_drawstate} array should describe a specific \e{rectangular area of the screen}, so that those areas can be erased and redrawn independently \dash so it must represent anything that appears in that area, even if it's sticking out from a graphic that logically lives in some other square. \b Temporary changes to the appearance of a square because of an ongoing completion flash. \b The current display mode, if a game provides more than one. (For example, the optional letters distinguishing the different coloured pegs in Guess.) All of this must be included in the \c{game_drawstate} representation, but should not be in the \c{game_state} at all. \cw{redraw()} will pull it all together from the \c{game_state}, the \c{game_ui}, and the animation and flash parameters. To make sure that \e{everything} affecting a square's appearance is included in this representation, it's a good idea to have a separate function for drawing a grid square, and deliberately \e{not} pass it a copy of the \c{game_state} or the \c{game_ui} at all. That way, if you want that function to draw anything differently, you \e{have} to do it by including that information in the representation of a square's appearance. But of course there are a couple of exceptions to this rule. A few things \e{don't} have to go in the \c{game_drawstate} array, and can safely be passed separately to the redraw-square function: \b Anything that remains completely fixed throughout the whole of a game, such as the clues provided by the puzzle. This is safe because a \c{game_drawstate} is never reused between puzzle instances: when you press New Game, a new \c{game_drawstate} will always be created from scratch. So the \c{game_drawstate} only needs to describe everything that might \e{change} during gameplay. If you have a sub-\cw{struct} in your \c{game_state} that describes immutable properties of the current game, as suggested in \k{writing-ref-counting}, then it's safe to pass \e{that substructure} to the redraw-square function, and have it retrieve that information directly. \b How far through a move animation the last redraw was. When \cw{redraw()} is called multiple times during an animated move, it's much easier to just assume that any square involved in the animation will \e{always} need redrawing. So \c{anim_length} can safely be passed separately to the redraw-square function \dash but you also have to remember to redraw a square if \e{either} its appearance is different from the last redraw \e{or} it's involved in an animation. \S{writing-howto-cursor} Drawing an object at only one position A common phenomenon is to have an object described in the \c{game_state} or the \c{game_ui} which can only be at one position. A cursor \dash probably specified in the \c{game_ui} \dash is a good example. In the \c{game_ui}, it would \e{obviously} be silly to have an array covering the whole game grid with a boolean flag stating whether the cursor was at each position. Doing that would waste space, would make it difficult to find the cursor in order to do anything with it, and would introduce the potential for synchronisation bugs in which you ended up with two cursors or none. The obviously sensible way to store a cursor in the \c{game_ui} is to have fields directly encoding the cursor's coordinates. However, it is a mistake to assume that the same logic applies to the \c{game_drawstate}. If you replicate the cursor position fields in the draw state, the redraw code will get very complicated. In the draw state, in fact, it \e{is} probably the right thing to have a cursor flag for every position in the grid, and make it part of the representation of each square's appearance, as described in \k{writing-howto-redraw}. So when you iterate over each square in \c{redraw()} working out its position, you set the \q{cursor here} flag in the representation of the square's appearance, if its coordinates match the cursor coordinates stored in the \c{game_ui}. This will automatically ensure that when the cursor moves, the redraw loop will redraw the square that \e{previously} contained the cursor and doesn't any more, and the one that now contains the cursor. \S{writing-keyboard-cursor} Implementing a keyboard-controlled cursor It is often useful to provide a keyboard control method in a basically mouse-controlled game. A keyboard-controlled cursor is best implemented by storing its location in the \c{game_ui} (since if it were in the \c{game_state} then the user would have to separately undo every cursor move operation). So the procedure would be: \b Put cursor position fields in the \c{game_ui}. \b \cw{interpret_move()} responds to arrow keys by modifying the cursor position fields and returning \cw{UI_UPDATE}. \b \cw{interpret_move()} responds to some other button \dash either \cw{CURSOR_SELECT} or some more specific thing like a number key \dash by actually performing a move based on the current cursor location. \b You might want an additional \c{game_ui} field stating whether the cursor is currently visible, and having it disappear when a mouse action occurs (so that it doesn't clutter the display when not actually in use). \b You might also want to automatically hide the cursor in \cw{changed_state()} when the current game state changes to one in which there is no move to make (which is the case in some types of completed game). \b \cw{redraw()} draws the cursor using the technique described in \k{writing-howto-cursor}. \S{writing-howto-dragging} Implementing draggable sprites Some games have a user interface which involves dragging some sort of game element around using the mouse. If you need to show a graphic moving smoothly over the top of other graphics, use a blitter (see \k{drawing-blitter} for the blitter API) to save the background underneath it. The typical scenario goes: \b Have a blitter field in the \c{game_drawstate}. \b Set the blitter field to \cw{NULL} in the game's \cw{new_drawstate()} function, since you don't yet know how big the piece of saved background needs to be. \b In the game's \cw{set_size()} function, once you know the size of the object you'll be dragging around the display and hence the required size of the blitter, actually allocate the blitter. \b In \cw{free_drawstate()}, free the blitter if it's not \cw{NULL}. \b In \cw{interpret_move()}, respond to mouse-down and mouse-drag events by updating some fields in the \cw{game_ui} which indicate that a drag is in progress. \b At the \e{very end} of \cw{redraw()}, after all other drawing has been done, draw the moving object if there is one. First save the background under the object in the blitter; then set a clip rectangle covering precisely the area you just saved (just in case anti-aliasing or some other error causes your drawing to go beyond the area you saved). Then draw the object, and call \cw{unclip()}. Finally, set a flag in the \cw{game_drawstate} that indicates that the blitter needs restoring. \b At the very start of \cw{redraw()}, before doing anything else at all, check the flag in the \cw{game_drawstate}, and if it says the blitter needs restoring then restore it. (Then clear the flag, so that this won't happen again in the next redraw if no moving object is drawn this time.) This way, you will be able to write the rest of the redraw function completely ignoring the dragged object, as if it were floating above your bitmap and being completely separate. \S{writing-ref-counting} Sharing large invariant data between all game states In some puzzles, there is a large amount of data which never changes between game states. The array of numbers in Dominosa is a good example. You \e{could} dynamically allocate a copy of that array in every \c{game_state}, and have \cw{dup_game()} make a fresh copy of it for every new \c{game_state}; but it would waste memory and time. A more efficient way is to use a reference-counted structure. \b Define a structure type containing the data in question, and also containing an integer reference count. \b Have a field in \c{game_state} which is a pointer to this structure. \b In \cw{new_game()}, when creating a fresh game state at the start of a new game, create an instance of this structure, initialise it with the invariant data, and set its reference count to 1. \b In \cw{dup_game()}, rather than making a copy of the structure for the new game state, simply set the new game state to point at the same copy of the structure, and increment its reference count. \b In \cw{free_game()}, decrement the reference count in the structure pointed to by the game state; if the count reaches zero, free the structure. This way, the invariant data will persist for only as long as it's genuinely needed; \e{as soon} as the last game state for a particular puzzle instance is freed, the invariant data for that puzzle will vanish as well. Reference counting is a very efficient form of garbage collection, when it works at all. (Which it does in this instance, of course, because there's no possibility of circular references.) \S{writing-flash-types} Implementing multiple types of flash In some games you need to flash in more than one different way. Mines, for example, flashes white when you win, and flashes red when you tread on a mine and die. The simple way to do this is: \b Have a field in the \c{game_ui} which describes the type of flash. \b In \cw{flash_length()}, examine the old and new game states to decide whether a flash is required and what type. Write the type of flash to the \c{game_ui} field whenever you return non-zero. \b In \cw{redraw()}, when you detect that \c{flash_time} is non-zero, examine the field in \c{game_ui} to decide which type of flash to draw. \cw{redraw()} will never be called with \c{flash_time} non-zero unless \cw{flash_length()} was first called to tell the mid-end that a flash was required; so whenever \cw{redraw()} notices that \c{flash_time} is non-zero, you can be sure that the field in \c{game_ui} is correctly set. \S{writing-move-anim} Animating game moves A number of puzzle types benefit from a quick animation of each move you make. For some games, such as Fifteen, this is particularly easy. Whenever \cw{redraw()} is called with \c{oldstate} non-\cw{NULL}, Fifteen simply compares the position of each tile in the two game states, and if the tile is not in the same place then it draws it some fraction of the way from its old position to its new position. This method copes automatically with undo. Other games are less obvious. In Sixteen, for example, you can't just draw each tile a fraction of the way from its old to its new position: if you did that, the end tile would zip very rapidly past all the others to get to the other end and that would look silly. (Worse, it would look inconsistent if the end tile was drawn on top going one way and on the bottom going the other way.) A useful trick here is to define a field or two in the game state that indicates what the last move was. \b Add a \q{last move} field to the \c{game_state} (or two or more fields if the move is complex enough to need them). \b \cw{new_game()} initialises this field to a null value for a new game state. \b \cw{execute_move()} sets up the field to reflect the move it just performed. \b \cw{redraw()} now needs to examine its \c{dir} parameter. If \c{dir} is positive, it determines the move being animated by looking at the last-move field in \c{newstate}; but if \c{dir} is negative, it has to look at the last-move field in \c{oldstate}, and invert whatever move it finds there. Note also that Sixteen needs to store the \e{direction} of the move, because you can't quite determine it by examining the row or column in question. You can in almost all cases, but when the row is precisely two squares long it doesn't work since a move in either direction looks the same. (You could argue that since moving a 2-element row left and right has the same effect, it doesn't matter which one you animate; but in fact it's very disorienting to click the arrow left and find the row moving right, and almost as bad to undo a move to the right and find the game animating \e{another} move to the right.) \S{writing-conditional-anim} Animating drag operations In Untangle, moves are made by dragging a node from an old position to a new position. Therefore, at the time when the move is initially made, it should not be animated, because the node has already been dragged to the right place and doesn't need moving there. However, it's nice to animate the same move if it's later undone or redone. This requires a bit of fiddling. The obvious approach is to have a flag in the \c{game_ui} which inhibits move animation, and to set that flag in \cw{interpret_move()}. The question is, when would the flag be reset again? The obvious place to do so is \cw{changed_state()}, which will be called once per move. But it will be called \e{before} \cw{anim_length()}, so if it resets the flag then \cw{anim_length()} will never see the flag set at all. The solution is to have \e{two} flags in a queue. \b Define two flags in \c{game_ui}; let's call them \q{current} and \q{next}. \b Set both to \cw{false} in \c{new_ui()}. \b When a drag operation completes in \cw{interpret_move()}, set the \q{next} flag to \cw{true}. \b Every time \cw{changed_state()} is called, set the value of \q{current} to the value in \q{next}, and then set the value of \q{next} to \cw{false}. \b That way, \q{current} will be \cw{true} \e{after} a call to \cw{changed_state()} if and only if that call to \cw{changed_state()} was the result of a drag operation processed by \cw{interpret_move()}. Any other call to \cw{changed_state()}, due to an Undo or a Redo or a Restart or a Solve, will leave \q{current} \cw{false}. \b So now \cw{anim_length()} can request a move animation if and only if the \q{current} flag is \e{not} set. \S{writing-cheating} Inhibiting the victory flash when Solve is used Many games flash when you complete them, as a visual congratulation for having got to the end of the puzzle. It often seems like a good idea to disable that flash when the puzzle is brought to a solved state by means of the Solve operation. This is easily done: \b Add a \q{cheated} flag to the \c{game_state}. \b Set this flag to \cw{false} in \cw{new_game()}. \b Have \cw{solve()} return a move description string which clearly identifies the move as a solve operation. \b Have \cw{execute_move()} respond to that clear identification by setting the \q{cheated} flag in the returned \c{game_state}. The flag will then be propagated to all subsequent game states, even if the user continues fiddling with the game after it is solved. \b \cw{flash_length()} now returns non-zero if \c{oldstate} is not completed and \c{newstate} is, \e{and} neither state has the \q{cheated} flag set. \H{writing-testing} Things to test once your puzzle is written Puzzle implementations written in this framework are self-testing as far as I could make them. Textual game and move descriptions, for example, are generated and parsed as part of the normal process of play. Therefore, if you can make moves in the game \e{at all} you can be reasonably confident that the mid-end serialisation interface will function correctly and you will be able to save your game. (By contrast, if I'd stuck with a single \cw{make_move()} function performing the jobs of both \cw{interpret_move()} and \cw{execute_move()}, and had separate functions to encode and decode a game state in string form, then those functions would not be used during normal play; so they could have been completely broken, and you'd never know it until you tried to save the game \dash which would have meant you'd have to test game saving \e{extensively} and make sure to test every possible type of game state. As an added bonus, doing it the way I did leads to smaller save files.) There is one exception to this, which is the string encoding of the \c{game_ui}. Most games do not store anything permanent in the \c{game_ui}, and hence do not need to put anything in its encode and decode functions; but if there is anything in there, you do need to test game loading and saving to ensure those functions work properly. It's also worth testing undo and redo of all operations, to ensure that the redraw and the animations (if any) work properly. Failing to animate undo properly seems to be a common error. Other than that, just use your common sense.