cc65 Users Guide <author>Ullrich von Bassewitz, <htmlurl url="mailto:uz@cc65.org" name="uz@cc65.org"> <date>03.09.2000, 02.10.2001, 2005-8-1 <abstract> cc65 is a C compiler for 6502 targets. It supports several 6502 based home computers like the Commodore and Atari machines, but it is easily retargetable. </abstract> <!-- Table of contents --> <toc> <!-- Begin the document --> <sect>Overview<p> cc65 was originally a C compiler for the Atari 8-bit machines written by John R. Dunning. In prior releases I've described the compiler by listing up the changes made by me. I have made many more changes in the meantime (and rewritten major parts of the compiler), so I will no longer do that, since the list would be too large and of no use to anyone. Instead I will describe the compiler in respect to the ANSI/ISO C standard. In fact, I'm planning a complete rewrite (that is, a complete new compiler) for the next release, since there are too many limitations in the current code, and removing these limitations would mean a rewrite of many more parts of the compiler. There are separate documents named <url url="library.html"> and <url url="funcref.html"> that cover the library that is available for the compiler. If you know C, and are interested in doing actual programming, the library documentation is probably of much more use than this document. If you need some hints for getting the best code out of the compiler, you may have a look at <url url="coding.html"> which covers some code generation issues. <sect>Usage<p> The compiler translates C files into files containing assembly code that may be translated by the ca65 macroassembler (for more information about the assembler, have a look at <url url="ca65.html">). <sect1>Command line option overview<p> The compiler may be called as follows: <tscreen><verb> --------------------------------------------------------------------------- Usage: cc65 [options] file Short options: -Cl Make local variables static -Dsym[=defn] Define a symbol -I dir Set an include directory search path -O Optimize code -Oi Optimize code, inline more code -Or Enable register variables -Os Inline some known functions -T Include source as comment -V Print the compiler version number -W Suppress warnings -d Debug mode -g Add debug info to object file -h Help (this text) -j Default characters are signed -o name Name the output file -r Enable register variables -t sys Set the target system -v Increase verbosity Long options: --add-source Include source as comment --bss-name seg Set the name of the BSS segment --check-stack Generate stack overflow checks --code-name seg Set the name of the CODE segment --codesize x Accept larger code by factor x --cpu type Set cpu type --create-dep Create a make dependency file --data-name seg Set the name of the DATA segment --debug Debug mode --debug-info Add debug info to object file --forget-inc-paths Forget include search paths --help Help (this text) --include-dir dir Set an include directory search path --register-space b Set space available for register variables --register-vars Enable register variables --rodata-name seg Set the name of the RODATA segment --signed-chars Default characters are signed --standard std Language standard (c89, c99, cc65) --static-locals Make local variables static --target sys Set the target system --verbose Increase verbosity --version Print the compiler version number --writable-strings Make string literals writable --------------------------------------------------------------------------- </verb></tscreen> <sect1>Command line options in detail<p> Here is a description of all the command line options: <descrip> <tag><tt>--bss-name seg</tt></tag> Set the name of the bss segment. <tag><tt>--check-stack</tt></tag> Tells the compiler to generate code that checks for stack overflows. See <tt><ref id="pragma-checkstack" name="#pragma checkstack"></tt> for an explanation of this feature. <tag><tt>--code-name seg</tt></tag> Set the name of the code segment. <label id="option-codesize"> <tag><tt>--codesize x</tt></tag> This options allows finer control about speed vs. size decisions in the code generation and optimization phases. It gives the allowed size increase factor (in percent). The default is 100 when not using <tt/-Oi/ and 200 when using <tt/-Oi/ (<tt/-Oi/ is the same as <tt/--codesize 200/). <tag><tt>--cpu CPU</tt></tag> A new, still experimental option. You may specify "6502" or "65C02" as the CPU. 6502 is the default, so this will not change anything. Specifying 65C02 will use a few 65C02 instructions when generating code. Don't expect too much from this option: It is still new (and may have bugs), and the additional instructions for the 65C02 are not that overwhelming. <tag><tt>--create-dep</tt></tag> Tells the compiler to generate a file containing the dependency list for the compiled module in makefile syntax. The file is named as the C input file with the extension replaced by <tt/.u/. <tag><tt>-d, --debug</tt></tag> Enables debug mode, something that should not be needed for mere mortals:-) <tag><tt>-D sym[=definition]</tt></tag> Define a macro on the command line. If no definition is given, the macro is defined to the value "1". <tag><tt>--forget-inc-paths</tt></tag> Forget the builtin include paths. This is most useful when building customized C or runtime libraries, in which case the standard header files should be ignored. <tag><tt>-g, --debug-info</tt></tag> This will cause the compiler to insert a <tt/.DEBUGINFO/ command into the generated assembler code. This will cause the assembler to include all symbols in a special section in the object file. <tag><tt>-h, --help</tt></tag> Print the short option summary shown above. <tag><tt>-o name</tt></tag> Specify the name of the output file. If you don't specify a name, the name of the C input file is used, with the extension replaced by ".s". <tag><tt>-r, --register-vars</tt></tag> <tt/-r/ will make the compiler honor the <tt/register/ keyword. Local variables may be placed in registers (which are actually zero page locations). There is some overhead involved with register variables, since the old contents of the registers must be saved and restored. Since register variables are of limited use without the optimizer, there is also a combined switch: <tt/-Or/ will enable both, the optimizer and register variables. For more information about register variables see <ref id="regvars" name="register variables">. The compiler setting can also be changed within the source file by using <tt><ref id="pragma-regvars" name="#pragma regvars"></tt>. <tag><tt>--register-space</tt></tag> This option takes a numeric parameter and is used to specify, how much zero page register space is available. Please note that just giving this option will not increase or decrease by itself, it will just tell the compiler about the available space. You will have to allocate that space yourself using an assembler module with the necessary allocations, and a linker configuration that matches the assembler module. The default value for this option is 6 (bytes). If you don't know what all this means, please don't use this option. <tag><tt>--rodata-name seg</tt></tag> Set the name of the rodata segment (the segment used for readonly data). <tag><tt>-j, --signed-chars</tt></tag> Using this option, you can make the default characters signed. Since the 6502 has no provisions for sign extending characters (which is needed on almost any load operation), this will make the code larger and slower. A better way is to declare characters explicitly as "signed" if needed. You can also use <tt><ref id="pragma-signedchars" name="#pragma signedchars"></tt> for better control of this option. <label id="option--standard"> <tag><tt>--standard std</tt></tag> This option allows to set the language standard supported. The argument is one of <itemize> <item>c89 <item>c99 <item>cc65 </itemize> <tag><tt>-t target, --target target</tt></tag> This option is used to set the target system. The target system determines things like the character set that is used for strings and character constants. The following target systems are supported: <itemize> <item>none <item>apple2 <item>apple2enh <item>atari <item>atmos <item>c16 (works also for the c116 with memory up to 32K) <item>c64 <item>c128 <item>cbm510 (CBM-II series with 40 column video) <item>cbm610 (all CBM-II II computers with 80 column video) <item>geos <item>lunix <item>lynx <item>nes <item>pet (all CBM PET systems except the 2001) <item>plus4 <item>supervision <item>vic20 </itemize> <tag><tt>-v, --verbose</tt></tag> Using this option, the compiler will be somewhat more verbose if errors or warnings are encountered. <tag><tt>--writable-strings</tt></tag> Make string literals writable by placing them into the data segment instead of the rodata segment. <tag><tt>-Cl, --static-locals</tt></tag> Use static storage for local variables instead of storage on the stack. Since the stack is emulated in software, this gives shorter and usually faster code, but the code is no longer reentrant. The difference between <tt/-Cl/ and declaring local variables as static yourself is, that initializer code is executed each time, the function is entered. So when using <tscreen><verb> void f (void) { unsigned a = 1; ... } </verb></tscreen> the variable <tt/a/ will always have the value <tt/1/ when entering the function and using <tt/-Cl/, while in <tscreen><verb> void f (void) { static unsigned a = 1; .... } </verb></tscreen> the variable <tt/a/ will have the value <tt/1/ only the first time that the function is entered, and will keep the old value from one call of the function to the next. You may also use <tt><ref id="pragma-staticlocals" name="#pragma staticlocals"></tt> to change this setting in your sources. <tag><tt>-I dir, --include-dir dir</tt></tag> Set a directory where the compiler searches for include files. You may use this option multiple times to add more than one directory to the search list. <label id="option-O"> <tag><tt>-O, -Oi, -Or, -Os</tt></tag> Enable an optimizer run over the produced code. Using <tt/-Oi/, the code generator will inline some code where otherwise a runtime functions would have been called, even if the generated code is larger. This will not only remove the overhead for a function call, but will make the code visible for the optimizer. <tt/-Oi/ is an alias for <tt/--codesize 200/. <tt/-Or/ will make the compiler honor the <tt/register/ keyword. Local variables may be placed in registers (which are actually zero page locations). There is some overhead involved with register variables, since the old contents of the registers must be saved and restored. In addition, the current implementation does not make good use of register variables, so using <tt/-Or/ may make your program even slower and larger. Use with care! Using <tt/-Os/ will force the compiler to inline some known functions from the C library like strlen. Note: This has two consequences: <p> <itemize> <item>You may not use names of standard C functions in your own code. If you do that, your program is not standard compliant anyway, but using <tt/-Os/ will actually break things. <p> <item>The inlined string and memory functions will not handle strings or memory areas larger than 255 bytes. Similarly, the inlined <tt/is..()/ functions will not work with values outside the char. range (such as <tt/EOF/). <p> </itemize> <p> It is possible to concatenate the modifiers for <tt/-O/. For example, to enable register variables and inlining of known functions, you may use <tt/-Ors/. <tag><tt>-T, --add-source</tt></tag> This include the source code as comments in the generated code. This is normally not needed. <tag><tt>-V, --version</tt></tag> Print the version number of the compiler. When submitting a bug report, please include the operating system you're using, and the compiler version. <label id="option-W"> <tag><tt>-W</tt></tag> This option will suppress any warnings generated by the compiler. Since any source file may be written in a manner that it will not produce compiler warnings, using this option is usually not a good idea. </descrip><p> <sect>Input and output<p> The compiler will accept one C file per invocation and create a file with the same base name, but with the extension replaced by ".s". The output file contains assembler code suitable for the use with the ca65 macro assembler. In addition to the paths named in the <tt/-I/ option on the command line, the directory named in the environment variable <tt/CC65_INC/ is added to the search path for include files on startup. <sect>Differences to the ISO standard<p> Here is a list of differences between the language, the compiler accepts, and the one defined by the ISO standard: <itemize> <item> The compiler allows unnamed parameters in parameter lists. The compiler will not issue warnings about unused parameters that don't have a name. This feature can be disabled with the <tt><ref id="option--standard" name="--standard"></tt> command line option. <p> <item> The compiler has some additional keywords: <p> <itemize> <item><tt/asm/ <item><tt/__asm__/ <item><tt/fastcall/ <item><tt/__fastcall__/ <item><tt/__AX__/ <item><tt/__EAX__/ <item><tt/__func__/ <item><tt/__attribute__/ </itemize> <p> The keywords without the underlines can be disabled with the <tt><ref id="option--standard" name="--standard"></tt> command line option. <p> <item> The datatypes "float" and "double" are not available. <p> <item> The compiler does not support bit fields. <p> <item> C Functions may not return structs (or unions), and structs may not be passed as parameters by value. However, struct assignment *is* possible. <p> <item> Part of the C library is available only with fastcall calling conventions (see below). It means that you must not mix pointers to those functions with pointers to user-written, not-fastcall functions. <p> </itemize> There may be some more minor differences I'm currently not aware of. The biggest problem is the missing float data type. With this limitation in mind, you should be able to write fairly portable code. <sect>Extensions<p> This cc65 version has some extensions to the ISO C standard. <itemize> <item> The compiler allows to insert assembler statements into the output file. The syntax is <tscreen><verb> asm (<string literal>[, optional parameters]) ; </verb></tscreen> or <tscreen><verb> __asm__ (<string literal>[, optional parameters]) ; </verb></tscreen> The first form is in the user namespace and is disabled if the <tt/-A/ switch is given. There is a whole section covering inline assembler statements, <ref id="inline-asm" name="see there">. <p> <item> There is a special calling convention named "fastcall". The syntax for a function declaration using fastcall is <tscreen><verb> <return type> fastcall <function name> (<parameter list>) </verb></tscreen> or <tscreen><verb> <return type> __fastcall__ <function name> (<parameter list>) </verb></tscreen> An example would be <tscreen><verb> void __fastcall__ f (unsigned char c) </verb></tscreen> The first form of the fastcall keyword is in the user namespace and can therefore be disabled with the <tt><ref id="option--standard" name="--standard"></tt> command line option. For functions declared as <tt/fastcall/, the rightmost parameter is not pushed on the stack but left in the primary register when the function is called. This will reduce the cost when calling assembler functions significantly, especially when the function itself is rather small. <p> <item> There are two pseudo variables named <tt/__AX__/ and <tt/__EAX__/. Both refer to the primary register that is used by the compiler to evaluate expressions or return function results. <tt/__AX__/ is of type <tt/unsigned int/ and <tt/__EAX__/ of type <tt/long unsigned int/ respectively. The pseudo variables may be used as lvalue and rvalue as every other variable. They are most useful together with short sequences of assembler code. For example, the macro <tscreen><verb> #define hi(x) \ (__AX__ = (x), \ asm ("txa"), \ asm ("ldx #$00"), \ __AX__) </verb></tscreen> will give the high byte of any unsigned value. <p> <item> Inside a function, the identifier <tt/__func__/ gives the name of the current function as a string. Outside of functions, <tt/__func__/ is undefined. Example: <tscreen><verb> #define PRINT_DEBUG(s) printf ("%s: %s\n", __func__, s); </verb></tscreen> The macro will print the name of the current function plus a given string. <p> <item> cc65 allows the initialization of <tt/void/ variables. This may be used to create variable structures that are more compatible with interfaces written for assembler languages. Here is an example: <tscreen><verb> void GCmd = { (char)3, (unsigned)0x2000, (unsigned)0x3000 }; </verb></tscreen> This will be translated as follows: <tscreen><verb> _GCmd: .byte 3 .word $2000 .word $3000 </verb></tscreen> Since the variable is of type <tt/void/ you may not use it as is. However, taking the address of the variable results in a <tt/void*/ which may be passed to any function expecting a pointer. See the <url url="geos.html" name="GEOS library document"> for examples on how to use this feature. <p> <item> cc65 implements flexible array struct members as defined in the C99 ISO standard. As an extension, these fields may be initialized. There are several exceptions, however (which is probably the reason why the standard does not define this feature, because it is highly unorthogonal). Flexible array members cannot be initialized ... <itemize> <item>... when defining an array of structs with flexible members. <item>... if such a struct is a member field of another struct which is not the last field. <item>... if the struct which contains a flexible array member is declared as <tt/register/, and the size and compiler settings do allow the compiler actually to place the struct into the register bank in the zero page. </itemize> Please note that -- as defined in the ISO C standard -- the <tt/sizeof/ operator returns the struct size with the flexible array member having size zero, even if it is initialized. <p> </itemize> <p> <sect>Predefined macros<p> The compiler defines several macros at startup: <descrip> <tag><tt>__CC65__</tt></tag> This macro is always defined. Its value is the version number of the compiler in hex. For example, version 2.10.1 of the compiler has this macro defined as <tt/0x02A1/. <tag><tt>__APPLE2__</tt></tag> This macro is defined if the target is the Apple ][ (-t apple2). <tag><tt>__APPLE2ENH__</tt></tag> This macro is defined if the target is the enhanced Apple //e (-t apple2enh). <tag><tt>__ATARI__</tt></tag> This macro is defined if the target is one of the Atari computers (400/800/130XL/800XL). <tag><tt>__ATMOS__</tt></tag> This macro is defined if the target is the Oric Atmos (-t atmos). <tag><tt>__CBM__</tt></tag> This macro is defined if the target system is one of the CBM targets. <tag><tt>__C16__</tt></tag> This macro is defined if the target is the c16 (-t c16). <tag><tt>__C64__</tt></tag> This macro is defined if the target is the c64 (-t c64). <tag><tt>__C128__</tt></tag> This macro is defined if the target is the c128 (-t c128). <tag><tt>__CBM510__</tt></tag> This macro is defined if the target is the CBM 500 series of computers. <tag><tt>__CBM610__</tt></tag> This macro is defined if the target is one of the CBM 600/700 family of computers (called B series in the US). <tag><tt>__GEOS__</tt></tag> This macro is defined if you are compiling for the GEOS system (-t geos). <tag><tt>__LUNIX__</tt></tag> This macro is defined if you are compiling for the LUnix system (-t lunix). <tag><tt>__LYNX__</tt></tag> This macro is defined if the target is the Atari Lynx (-t lynx). <tag><tt>__NES__</tt></tag> This macro is defined if the target is the NES (-t nes). <tag><tt>__PET__</tt></tag> This macro is defined if the target is the PET family of computers (-t pet). <tag><tt>__PLUS4__</tt></tag> This macro is defined if the target is the plus/4 (-t plus4). <tag><tt>__SUPERVISION__</tt></tag> This macro is defined if the target is the supervision (-t supervision). <tag><tt>__VIC20__</tt></tag> This macro is defined if the target is the vic20 (-t vic20). <tag><tt>__FILE__</tt></tag> This macro expands to a string containing the name of the C source file. <tag><tt>__LINE__</tt></tag> This macro expands to the current line number. <tag><tt>__CC65_STD__</tt></tag> This macro is defined to one of the following depending on the <tt><ref id="option--standard" name="--standard"></tt> command line option: <itemize> <item><tt/__CC65_STD_C89__/ <item><tt/__CC65_STD_C99__/ <item><tt/__CC65_STD_CC65__/ </itemize> <tag><tt>__OPT__</tt></tag> Is defined if the compiler was called with the <tt/-O/ command line option. <tag><tt>__OPT_i__</tt></tag> Is defined if the compiler was called with the <tt/-Oi/ command line option. <tag><tt>__OPT_r__</tt></tag> Is defined if the compiler was called with the <tt/-Or/ command line option. <tag><tt>__OPT_s__</tt></tag> Is defined if the compiler was called with the <tt/-Os/ command line option. </descrip> <sect>#pragmas<label id="pragmas"><p> The compiler understands some pragmas that may be used to change code generation and other stuff. Some of these pragmas understand a special form: If the first parameter is <tt/push/, the old value is saved onto a stack before changing it. The value may later be restored by using the <tt/pop/ parameter with the <tt/#pragma/. <sect1><tt>#pragma bssseg ([push,]<name>)</tt><p> This pragma changes the name used for the BSS segment (the BSS segment is used to store uninitialized data). The argument is a string enclosed in double quotes. Note: The default linker configuration file does only map the standard segments. If you use other segments, you have to create a new linker configuration file. Beware: The startup code will zero only the default BSS segment. If you use another BSS segment, you have to do that yourself, otherwise uninitialized variables do not have the value zero. The <tt/#pragma/ understands the push and pop parameters as explained above. Example: <tscreen><verb> #pragma bssseg ("MyBSS") </verb></tscreen> <sect1><tt>#pragma charmap (<index>, <code>)</tt><p> Each literal string and each literal character in the source is translated by use of a translation table. This translation table is preset when the compiler is started depending on the target system, for example to map ISO-8859-1 characters into PETSCII if the target is a commodore machine. This pragma allows to change entries in the translation table, so the translation for individual characters, or even the complete table may be adjusted. Both arguments are assumed to be unsigned characters with a valid range of 1-255. Beware of two pitfalls: <itemize> <item>The character index is actually the code of the character in the C source, so character mappings do always depend on the source character set. This means that <tt/#pragma charmap/ is not portable -- it depends on the build environment. <item>While it is possible to use character literals as indices, the result may be somewhat unexpected, since character literals are itself translated. For this reason I would suggest to avoid character literals and use numeric character codes instead. </itemize> Example: <tscreen><verb> /* Use a space wherever an 'a' occurs in ISO-8859-1 source */ #pragma charmap (0x61, 0x20); </verb></tscreen> <sect1><tt>#pragma checkstack ([push,]on|off)</tt><label id="pragma-checkstack"><p> Tells the compiler to insert calls to a stack checking subroutine to detect stack overflows. The stack checking code will lead to somewhat larger and slower programs, so you may want to use this pragma when debugging your program and switch it off for the release version. If a stack overflow is detected, the program is aborted. If the argument is "off", stack checks are disabled (the default), otherwise they're enabled. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma codeseg ([push,]<name>)</tt><p> This pragma changes the name used for the CODE segment (the CODE segment is used to store executable code). The argument is a string enclosed in double quotes. Note: The default linker configuration file does only map the standard segments. If you use other segments, you have to create a new linker configuration file. The <tt/#pragma/ understands the push and pop parameters as explained above. Example: <tscreen><verb> #pragma codeseg ("MyCODE") </verb></tscreen> <sect1><tt>#pragma codesize ([push,]<int>)</tt><label id="pragma-codesize"><p> This pragma allows finer control about speed vs. size decisions in the code generation and optimization phase. It gives the allowed size increase factor (in percent). The default is can be changed by use of the <tt/<ref id="option-codesize" name="--codesize">/ compiler option. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma dataseg ([push,]<name>)</tt><p> This pragma changes the name used for the DATA segment (the DATA segment is used to store initialized data). The argument is a string enclosed in double quotes. Note: The default linker configuration file does only map the standard segments. If you use other segments, you have to create a new linker configuration file. The <tt/#pragma/ understands the push and pop parameters as explained above. Example: <tscreen><verb> #pragma dataseg ("MyDATA") </verb></tscreen> <sect1><tt>#pragma optimize ([push,]on|off)</tt><label id="pragma-optimize"><p> Switch optimization on or off. If the argument is "off", optimization is disabled, otherwise it is enabled. Please note that this pragma only effects whole functions. The setting in effect when the function is encountered will determine if the generated code is optimized or not. Optimization and code generation is also controlled by the <ref id="pragma-codesize" name="codesize pragma">. The default is "off", but may be changed with the <tt/<ref name="-O" id="option-O">/ compiler option. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma rodataseg ([push,]<name>)</tt><p> This pragma changes the name used for the RODATA segment (the RODATA segment is used to store readonly data). The argument is a string enclosed in double quotes. Note: The default linker configuration file does only map the standard segments. If you use other segments, you have to create a new linker configuration file. The <tt/#pragma/ understands the push and pop parameters as explained above. Example: <tscreen><verb> #pragma rodataseg ("MyRODATA") </verb></tscreen> <sect1><tt>#pragma regvaraddr ([push,]on|off)</tt><p> The compiler does not allow to take the address of register variables. The regvaraddr pragma changes this. Taking the address of a register variable is allowed after using this pragma with "on" as argument. Using "off" as an argument switches back to the default behaviour. Beware: The C standard does not allow taking the address of a variable declared as register. So your programs become non-portable if you use this pragma. In addition, your program may not work. This is usually the case if a subroutine is called with the address of a register variable, and this subroutine (or a subroutine called from there) uses register variables. So be careful with this #pragma. The <tt/#pragma/ understands the push and pop parameters as explained above. Example: <tscreen><verb> #pragma regvaraddr(on) /* Allow taking the address * of register variables */ </verb></tscreen> <sect1><tt>#pragma regvars ([push,]on|off)</tt><label id="pragma-regvars"><p> Enables or disables use of register variables. If register variables are disabled (the default), the <tt/register/ keyword is ignored. Register variables are explained in more detail in <ref id="regvars" name="a separate chapter">. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma signedchars ([push,]on|off)</tt><label id="pragma-signedchars"><p> Changes the signedness of the default character type. If the argument is "on", default characters are signed, otherwise characters are unsigned. The compiler default is to make characters unsigned since this creates a lot better code. This default may be overridden by the <tt/--signed-chars/ command line option. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma staticlocals ([push,]on|off)</tt><label id="pragma-staticlocals"<p> Use variables in the bss segment instead of variables on the stack. This pragma changes the default set by the compiler option <tt/-Cl/. If the argument is "on", local variables are allocated in the BSS segment, leading to shorter and in most cases faster, but non-reentrant code. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma warn ([push,]on|off)</tt><label id="pragma-warn"><p> Switch compiler warnings on or off. If the argument is "off", warnings are disabled, otherwise they're enabled. The default is "on", but may be changed with the <tt/<ref name="-W" id="option-W">/ compiler option. The <tt/#pragma/ understands the push and pop parameters as explained above. <sect1><tt>#pragma zpsym (<name>)</tt><p> Tell the compiler that the -- previously as external declared -- symbol with the given name is a zero page symbol (usually from an assembler file). The compiler will create a matching import declaration for the assembler. Example: <tscreen><verb> extern int foo; #pragma zpsym ("foo"); /* foo is in the zeropage */ </verb></tscreen> <sect>Register variables<label id="regvars"><p> The runtime for all supported platforms has 6 bytes of zero page space available for register variables (this could be increased, but I think it's a good value). So you can declare register variables up to a total size of 6 per function. The compiler will allocate register space on a "first come, first served" base and convert any <tt/register/ declarations that exceed the available register space silently to <tt/auto/. Parameters can also be declared as <tt/register/, this will in fact give slightly shorter code than using a register variable. Since a function must save the current values of the registers on entry and restore them on exit, there is an overhead associated with register variables, and this overhead is quite high (about 20 bytes per variable). This means that just declaring anything as <tt/register/ is not a good idea. The best use for register variables are pointers, especially those that point to structures. The magic number here is about 3 uses of a struct field: If the function contains this number or even more, the generated code will be usually shorter and faster when using a register variable for the struct pointer. The reason for this is that the register variable can in many cases be used as a pointer directly. Having a pointer in an auto variable means that this pointer must first be copied into a zero page location, before it can be dereferenced. Second best use for register variables are counters. However, there is not much difference in the code generated for counters, so you will need at least 100 operations on this variable (for example in a loop) to make it worth the trouble. The only savings you get here are by the use of a zero page variable instead of one on the stack or in the data segment. Register variables must be explicitly enabled by using <tt/-Or/ or <tt/-r/ on the command line. Register variables are only accepted on function top level, register variables declared in interior blocks are silently converted to <tt/auto/. With register variables disabled, all variables declared as <tt/register/ are actually auto variables. Please take care when using register variables: While they are helpful and can lead to a tremendous speedup when used correctly, improper usage will cause bloated code and a slowdown. <sect>Inline assembler<label id="inline-asm"><p> The compiler allows to insert assembler statements into the output file. The syntax is <tscreen><verb> asm (<string literal>[, optional parameters]) ; </verb></tscreen> or <tscreen><verb> __asm__ (<string literal>[, optional parameters]) ; </verb></tscreen> <p> The first form is in the user namespace and is disabled by <tt><ref id="option--standard" name="--standard"></tt> if the argument is not <tt/cc65/. The asm statement may be used inside a function and on global file level. An inline assembler statement is a primary expression, so it may also be used as part of an expression. Please note however that the result of an expression containing just an inline assembler statement is always of type <tt/void/. The contents of the string literal are preparsed by the compiler and inserted into the generated assembly output, so that the can be further processed by the backend and especially the optimizer. For this reason, the compiler does only allow regular 6502 opcodes to be used with the inline assembler. Pseudo instructions (like <tt/.import/, <tt/.byte/ and so on) are <em/not/ allowed, even if the ca65 assembler (which is used to translate the generated assembler code) would accept them. The builtin inline assembler is not a replacement for the full blown macro assembler which comes with the compiler. Note: Inline assembler statements are subject to all optimizations done by the compiler. There is currently no way to protect an inline assembler statement from being moved or removed completely by the optimizer. If in doubt, check the generated assembler output, or disable optimizations. The string literal may contain format specifiers from the following list. For each format specifier, an argument is expected which is inserted instead of the format specifier before passing the assembly code line to the backend. <itemize> <item><tt/%b/ - Numerical 8-bit value <item><tt/%w/ - Numerical 16-bit value <item><tt/%l/ - Numerical 32-bit value <item><tt/%v/ - Assembler name of a (global) variable or function <item><tt/%o/ - Stack offset of a (local) variable <item><tt/%g/ - Assembler name of a C label <item><tt/%s/ - The argument is converted to a string <item><tt/%%/ - The % sign itself </itemize><p> Using these format specifiers, you can access C <tt/#defines/, variables or similar stuff from the inline assembler. For example, to load the value of a C <tt/#define/ into the Y register, one would use <tscreen><verb> #define OFFS 23 __asm__ ("ldy #%b", OFFS); </verb></tscreen> Or, to access a struct member of a static variable: <tscreen><verb> typedef struct { unsigned char x; unsigned char y; unsigned char color; } pixel_t; static pixel_t pixel; __asm__ ("ldy #%b", offsetof(pixel_t, color)); __asm__ ("lda %v,y", pixel); </verb></tscreen> <p> Note: Do not embed the assembler labels that are used as names of global variables or functions into your asm statements. Code like this <tscreen><verb> int foo; int bar () { return 1; } __asm__ ("lda _foo"); /* DON'T DO THAT! */ ... __asm__ ("jsr _bar"); /* DON'T DO THAT EITHER! */ </verb></tscreen> <p> may stop working if the way, the compiler generates these names is changed in a future version. Instead use the format specifiers from the table above: <tscreen><verb> __asm__ ("lda %v", foo); /* OK */ ... __asm__ ("jsr %v", bar); /* OK */ </verb></tscreen> <p> <sect>Bugs/Feedback<p> If you have problems using the compiler, if you find any bugs, or if you're doing something interesting with it, I would be glad to hear from you. Feel free to contact me by email (<htmlurl url="mailto:uz@cc65.org" name="uz@cc65.org">). <sect>Copyright<p> This is the original compiler copyright: <tscreen><verb> -------------------------------------------------------------------------- -*- Mode: Text -*- This is the copyright notice for RA65, LINK65, LIBR65, and other Atari 8-bit programs. Said programs are Copyright 1989, by John R. Dunning. All rights reserved, with the following exceptions: Anyone may copy or redistribute these programs, provided that: 1: You don't charge anything for the copy. It is permissable to charge a nominal fee for media, etc. 2: All source code and documentation for the programs is made available as part of the distribution. 3: This copyright notice is preserved verbatim, and included in the distribution. You are allowed to modify these programs, and redistribute the modified versions, provided that the modifications are clearly noted. There is NO WARRANTY with this software, it comes as is, and is distributed in the hope that it may be useful. This copyright notice applies to any program which contains this text, or the refers to this file. This copyright notice is based on the one published by the Free Software Foundation, sometimes known as the GNU project. The idea is the same as theirs, ie the software is free, and is intended to stay that way. Everybody has the right to copy, modify, and re- distribute this software. Nobody has the right to prevent anyone else from copying, modifying or redistributing it. -------------------------------------------------------------------------- </verb></tscreen> Small parts of the compiler (parts of the preprocessor and main parser) are still covered by this copyright. The main portion is covered by the usual cc65 license, which reads: This software is provided 'as-is', without any expressed or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: <enum> <item> The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. <item> Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. <item> This notice may not be removed or altered from any source distribution. </enum> </article>