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Tidy up
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.gitignore
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*.o
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/kernel/user.h
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TRICKS.txt
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TRICKS.txt
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This file describe tricks and conventions that are used throughout the code and
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might need explanation.
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*** Quickies
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or a: Equivalent to "cp 0", but results in a shorter opcode.
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xor a: sets A to 0 more efficiently than ld a, 0
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and 0xbf: Given a letter in the a-z range, changes it to its uppercase value
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if it's already uppercased, then it stays that way.
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*** Z flag for results
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Z if almost always used as a success indicator for routines. Set for success,
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Reset for failure. "xor a" (destroys A) and "cp a" (preserves A) are used to
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ensure Z is set. To ensure that it is reset, it's a bit more complicated and
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"unsetZ" routine exists for that, although that in certain circumstances,
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"inc a \ dec a" or "or a" can work.
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*** Little endian
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z80 is little endian in its 16-bit loading operations. For example, "ld hl, (0)"
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will load the contents of memory address 0 in L and memory address 1 in H. This
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little-endianess is followed by Collapse OS in most situations. When it's not,
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it's specified in comments.
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This get a bit awkward with regards to 32-bit. There are no "native" z80 32-bit
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operations, so z80 doesn't mandate an alignment. In Collapse OS, 32-bit numbers
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are stored as "big endian pair of little endian 16-bit numbers". For example,
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if "ld dehl, (0)" existed and if the first 4 bytes of memory were 0x01, 0x02,
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0x03 and 0x04, then DE (being the "high" word) would be 0x0201 and HL would be
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0x0403.
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*** DAA
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When it comes to dealing with decimals, the DAA instruction, which look a bit
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obscur, can be very useful. It transforms the result of a previous arithmetic
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operation involving two BCD (binary coded decimal, one digit in high nibble,
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the other digit in low nibble. For example, 0x99 represents 99) into a valid
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BCD. For example, 0x12+0x19=0x2b, but after calling DAA, it will be 0x31.
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To clear misunderstanding: this does **not** transform an arbitrary value into
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BCD. For example, "ld a, 0xff \ daa" isn't going to magically give you a binary
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coded 255 (how could it?). This is designed to be ran after an arithmetic
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operation.
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A common trick to transform an arbitrary number to BCD is to loop 8 times over
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your bitstream, SLA your bits out of your binary value and then run
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"adc a, a \ daa" over it (with provisions for carries if you expect numbers
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over 99).
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