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308 lines
9.8 KiB
Plaintext
308 lines
9.8 KiB
Plaintext
<!doctype linuxdoc system>
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<article>
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<title>cc65 coding hints
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<author><url url="mailto:uz@cc65.org" name="Ullrich von Bassewitz">
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<abstract>
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How to generate the most effective code with cc65.
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</abstract>
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<sect>Use prototypes<p>
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This will not only help to find errors between separate modules, it will also
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generate better code, since the compiler must not assume that a variable sized
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parameter list is in place and must not pass the argument count to the called
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function. This will lead to shorter and faster code.
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<sect>Don't declare auto variables in nested function blocks<p>
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Variable declarations in nested blocks are usually a good thing. But with
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cc65, there is a drawback: Since the compiler generates code in one pass, it
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must create the variables on the stack each time the block is entered and
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destroy them when the block is left. This causes a speed penalty and larger
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code.
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<sect>Remember that the compiler does no high level optimizations<p>
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The compiler needs hints from you about the code to generate. It will try to
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optimize the generated code, but follow the outline you gave in your C
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program. So for example, when accessing indexed data structures, get a pointer
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to the element and use this pointer instead of calculating the index again and
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again. If you want to have your loops unrolled, or loop invariant code moved
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outside the loop, you have to do that yourself.
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<sect>Longs are slow!<p>
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While long support is necessary for some things, it's really, really slow on
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the 6502. Remember that any long variable will use 4 bytes of memory, and any
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operation works on double the data compared to an int.
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<sect>Use unsigned types wherever possible<p>
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The 6502 CPU has no opcodes to handle signed values greater than 8 bit. So
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sign extension, test of signedness etc. has to be done with extra code. As a
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consequence, the code to handle signed operations is usually a bit larger and
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slower than the same code for unsigned types.
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<sect>Use chars instead of ints if possible<p>
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While in arithmetic operations, chars are immidiately promoted to ints, they
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are passed as chars in parameter lists and are accessed as chars in variables.
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The code generated is usually not much smaller, but it is faster, since
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accessing chars is faster. For several operations, the generated code may be
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better if intermediate results that are known not to be larger than 8 bit are
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casted to chars.
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You should especially use unsigned chars for loop control variables if the
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loop is known not to execute more than 255 times.
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<sect>Make the size of your array elements one of 1, 2, 4, 8<p>
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When indexing into an array, the compiler has to calculate the byte offset
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into the array, which is the index multiplied by the size of one element. When
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doing the multiplication, the compiler will do a strength reduction, that is,
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replace the multiplication by a shift if possible. For the values 2, 4 and 8,
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there are even more specialized subroutines available. So, array access is
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fastest when using one of these sizes.
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<sect>Expressions are evaluated from left to right<p>
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Since cc65 is not building an explicit expression tree when parsing an
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expression, constant subexpressions may not be detected and optimized properly
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if you don't help. Look at this example:
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<tscreen><verb>
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#define OFFS 4
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int i;
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i = i + OFFS + 3;
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</verb></tscreen>
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The expression is parsed from left to right, that means, the compiler sees 'i',
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and puts it contents into the secondary register. Next is OFFS, which is
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constant. The compiler emits code to add a constant to the secondary register.
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Same thing again for the constant 3. So the code produced contains a fetch
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of 'i', two additions of constants, and a store (into 'i'). Unfortunately, the
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compiler does not see, that "OFFS + 3" is a constant for itself, since it does
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its evaluation from left to right. There are some ways to help the compiler
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to recognize expression like this:
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<enum>
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<item>Write "i = OFFS + 3 + i;". Since the first and second operand are
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constant, the compiler will evaluate them at compile time reducing the code to
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a fetch, one addition (secondary + constant) and one store.
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<item>Write "i = i + (OFFS + 3)". When seeing the opening parenthesis, the
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compiler will start a new expression evaluation for the stuff in the braces,
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and since all operands in the subexpression are constant, it will detect this
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and reduce the code to one fetch, one addition and one store.
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</enum>
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<sect>Use the preincrement and predecrement operators<p>
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The compiler is not always smart enough to figure out, if the rvalue of an
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increment is used or not. So it has to save and restore that value when
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producing code for the postincrement and postdecrement operators, even if this
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value is never used. To avoid the additional overhead, use the preincrement
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and predecrement operators if you don't need the resulting value. That means,
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use
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<tscreen><verb>
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...
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++i;
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...
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</verb></tscreen>
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instead of
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<tscreen><verb>
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...
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i++;
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...
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</verb></tscreen>
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<sect>Use constants to access absolute memory locations<p>
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The compiler produces optimized code, if the value of a pointer is a constant.
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So, to access direct memory locations, use
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<tscreen><verb>
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#define VDC_STATUS 0xD601
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*(char*)VDC_STATUS = 0x01;
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</verb></tscreen>
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That will be translated to
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<tscreen><verb>
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lda #$01
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sta $D601
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</verb></tscreen>
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The constant value detection works also for struct pointers and arrays, if the
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subscript is a constant. So
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<tscreen><verb>
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#define VDC ((unsigned char*)0xD600)
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#define STATUS 0x01
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VDC[STATUS] = 0x01;
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</verb></tscreen>
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will also work.
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If you first load the constant into a variable and use that variable to access
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an absolute memory location, the generated code will be much slower, since the
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compiler does not know anything about the contents of the variable.
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<sect>Use initialized local variables<p>
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Initialization of local variables when declaring them gives shorter and faster
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code. So, use
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<tscreen><verb>
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int i = 1;
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</verb></tscreen>
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instead of
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<tscreen><verb>
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int i;
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i = 1;
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</verb></tscreen>
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But beware: To maximize your savings, don't mix uninitialized and initialized
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variables. Create one block of initialized variables and one of uniniitalized
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ones. The reason for this is, that the compiler will sum up the space needed
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for uninitialized variables as long as possible, and then allocate the space
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once for all these variables. If you mix uninitialized and initialized
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variables, you force the compiler to allocate space for the uninitialized
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variables each time, it parses an initialized one. So do this:
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<tscreen><verb>
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int i, j;
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int a = 3;
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int b = 0;
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</verb></tscreen>
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instead of
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<tscreen><verb>
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int i;
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int a = 3;
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int j;
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int b = 0;
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</verb></tscreen>
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The latter will work, but will create larger and slower code.
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<sect>Use the array operator [] even for pointers<p>
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When addressing an array via a pointer, don't use the plus and dereference
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operators, but the array operator. This will generate better code in some
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common cases.
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Don't use
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<tscreen><verb>
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char* a;
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char b, c;
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char b = *(a + c);
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</verb></tscreen>
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Use
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<tscreen><verb>
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char* a;
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char b, c;
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char b = a[c];
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</verb></tscreen>
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instead.
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<sect>Use register variables with care<p>
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Register variables may give faster and shorter code, but they do also have an
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overhead. Register variables are actually zero page locations, so using them
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saves roughly one cycle per access. The calling routine may also use register
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variables, so the old values have to be saved on function entry and restored
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on exit. Saving an d restoring has an overhead of about 70 cycles per 2 byte
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variable. It is easy to see, that - apart from the additional code that is
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needed to save and restore the values - you need to make heavy use of a
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variable to justify the overhead.
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As a general rule: Use register variables only for pointers that are
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dereferenced several times in your function, or for heavily used induction
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variables in a loop (with several 100 accesses).
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When declaring register variables, try to keep them together, because this
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will allow the compiler to save and restore the old values in one chunk, and
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not in several.
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And remember: Register variables must be enabled with <tt/-r/ or <tt/-Or/.
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<sect>Decimal constants greater than 0x7FFF are actually long ints<p>
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The language rules for constant numeric values specify that decimal constants
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without a type suffix that are not in integer range must be of type long int
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or unsigned long int. So a simple constant like 40000 is of type long int!
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This is often unexpected and may cause an expression to be evaluated with 32
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bits. While in many cases the compiler takes care about it, in some places it
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can't. So be careful when you get a warning like
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<tscreen><verb>
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test.c(7): Warning: Constant is long
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</verb></tscreen>
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Use the <tt/U/, <tt/L/ or <tt/UL/ suffixes to tell the compiler the desired
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type of a numeric constant.
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<sect>Access to parameters in variadic functions is expensive<p>
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Since cc65 has the "wrong" calling order, the location of the fixed parameters
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in a variadic function (a function with a variable parameter list) depends on
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the number and size of variable arguments passed. Since this number and size
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is unknown at compile time, the compiler will generate code to calculate the
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location on the stack when needed.
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Because of this additional code, accessing the fixed parameters in a variadic
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function is much more expensive than access to parameters in a "normal"
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function. Unfortunately, this additional code is also invisible to the
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programmer, so it is easy to forget.
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As a rule of thumb, if you access such a parameter more than once, you should
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think about copying it into a normal variable and using this variable instead.
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</article>
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