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544 lines
15 KiB
Plaintext
544 lines
15 KiB
Plaintext
C02 Design Considerations
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Variable Storage
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================
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Zero Page
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---------
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The 6502 has a Zero Page addressing mode. This differs from the absolute
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addressing mode in that the address operand is only one byte instead of
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two and the instructions take less cycles to execute.
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Also, some systems have very limited RAM, requiring all variables to be
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stored in zero page. One example is the Atari 2600, which maps the 128
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bytes of RAM in the RIOT chip to the range $80-$8F and mirrors it at
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$180-$18F (for the machine stack).
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To allow the use of zero page variables, the compiler recognizes the
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"zeropage" declaration modifier and the "#pragma zeropage" directive,
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the latter of which specifies a base address for allocating zero page
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variables.
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I may add a -Z command line option to allow the specification of the
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zero page variable base address.
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ROM Based Code
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--------------
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For compiled programs that will reside in ROM, such as an EPROM or a
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cartridge, variables will need to reside in a separate memory area than
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the program.
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The compiler normally allocates all variables directly after the generated
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code, const variables first and regular variables afterward. In addition,
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the regular variables are all all allocated as zero bytes in the assembled
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object code, which can unnecesarilly inflate the size of the generated
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binary file.
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The compiler allows the location of non-const variables to be specified
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using the "#pragma rambase" directive.
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I may add a -R command line option to allow the specification of the RAM
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variable base address.
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Read/Write Variables
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--------------------
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Some systems used different memory addresses for reading and writing to
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RAM. One example is Atari 2600 catridges with RAM. The SARA Superchip
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contained 128 bytes of RAM, which were written at addresses $F000 through
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$F01F and read from addresses $F080 through $F0FF, while CBS RAM+ had 256
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bytes which were written from $F000 though $F0FF and read from $F100
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through $F1FF.
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To allow for this, the compiler recognizes an additional directive,
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"#pragma writebase" directive. In this case the "#pragma rambase"
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will specify the base address for reads. When a write base address is
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specified, the compiler will allocate all variables using the read base
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address and generate an offset, which will be included in all variable
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assignments. Thus the code
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#pragma rambase $F100
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#pragma writebase $F000
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char b,c;
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c = b;
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would generate the assembly code
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LDA B
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STA C-256
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B EQU $F100
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C EQU $F101
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I may add a -W command line option to allow the specification of the write
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base address.
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Variable Types
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==============
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Pointers
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--------
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The 6502 differs from nearly all other microprocessors by not having
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a 16 bit index register, instead using indirect indexed mode in
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conjunction with zero page.
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On other processors, it would be trivial to dereference a pointer
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stored anywhere in memory. For example, on the 6800:
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LDX P ;N = *P
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LDAA IX
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There is no direct equivalent on the 6502, but by using indirect
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indexed mode, any zero page variable pair can be used as a pointer:
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LDY #0 ;N = *P
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LDA (P),Y
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Additionally, accessing elements of a dereferenced zero page pointer
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is just as trivial:
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LDY I ;N = *P[I]
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LDA (P),Y
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expr ;N - *P[expr]
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TAY
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LDA (P),Y
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However, trying to use a 16-bit value stored outside of zero-page
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would take extra code and require using a a zero page byte pair:
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LDY P ;N = *P
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STY ZP
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LDY P+1
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STY ZP+1
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LDY #0
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LDA (ZP),Y
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This violates two principles of the C02 design philosophy: that
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each token correspond to one or two machine instructions and
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that the compiler is completely agnostic of the system configuration.
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Therefore, if pointers are implemented, they will have to be in
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zero page.
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Implementation:
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Declaration of a pointer should use two bytes of zero page storage,
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the address of which would be taken from the free zero page space
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specified by the #pragma zeropage directive.
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P EQU $80 ;char *p
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Q EQU $82 ;char *q
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Any pointers declared in a header file would added to the variable
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table but not allocated, so would be defined in the accompanying
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assembly file:
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char *dst; //stddef.h02
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char dstlo,dsthi;
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DST EQU $30 ;stddef.a02
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DSTLO EQU $30
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DSTHI EQU $31
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Since they are 16-bit values, raw pointers cannot be passed into
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used directly in expressions. But could be used in standalone
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assignments:
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LDX Q ;p = q
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STX P
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LDY Q+1 ;X is used for LSB and Y as MSB to match
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STY P+1 ;the address passing convention for functions
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Likewise if a 16-bit integer variable type was added to C02,
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then one could be assigned to the other using the exact same
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assembly code.
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A dereferenced pointer can be used anywhere an array references
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is allowed and would be subject to the same restrictions.
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A raw pointer used as an argument to a function will be passed
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using the same convention as an address:
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LDY P+1 ;func(p)
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LDX P
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JSR FUNC
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JSR FUNC ;p = func()
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STY P+1
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STX P
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Since pointers are zero page the address of operator on a pointer
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will generate a char value:
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LDA #P ;&p
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This will allow passing of pointers for use inside of functions
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using indexed mode:
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LDA #P ;inc(&p)
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JSR FUNC
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TAX ;void inc()
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INC ($00,X)
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RTS
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The memio module makes extensive use of pointer addresses as
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function arguments.
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Structs
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-------
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For the declarations
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STRUCT RECORD { CHAR NAME[8]; CHAR INDEX; CHAR DATA[128]; };
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STRUCT RECORD REC;
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references to the members of the struct REC will generate the code:
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XXX REC+$09 ;REC.INDEX
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LDX I ;REC.DATA[I]
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XXX REC+$0A,X
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Using the address of operator on a struct member generates assembly
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code with parentherical expressions, which are not recognized by all
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assemblers:
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LDY #>(REC+$0A) ;FUNC(&REC.DATA)
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LDX #<(REC+$0A)
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JSR FUNC
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The compiler could optimize the generation of code for references
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to the first member of a struct, producing
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XXX REC ;REC.NAME
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instead of
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XXX REC+$00 ;REC.NAME
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but the machine code produced by the assembler should be identical
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in either case.
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Expression Evaluation
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=====================
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Array Indexes
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-------------
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Array indexing normally uses the X register and indexed addressing mode:
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LDX I ;R[I]
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XXX R,X
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If the index is a constant or literal, absolute addressing is used:
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LDA R+1 ;R[1]
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XXX S+0 ;S[0]
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Specifying a register as the index also uses indexed addressing mode:
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TAX ;R[A]
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XXX R,X
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XXX R,Y ;R[Y]
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XXX R,X ;R[X]
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Allowing for an expression as the index in the first term of an
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expression uses only one extra byte of code and two machine cycles:
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expression ;R[expr]
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TAX
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LDAA R,X
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while in any other termm is uses an extra three extra bytes of code
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and ten machine cycles:
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PHA ;R[expr]
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expr code ;code to evaluate the expression
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TAX
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PLA
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XXX R,X
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compared to the extra four to six bytes and six to eight machine cycles
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used by the equivalent C02 code required to achieve the same result:
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expr code ;Z = expr
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STA Z
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LDX Z ;R[Z]
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XXX R,X
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Function Calls
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--------------
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A function call in the first term of an expression requires additional
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processing by the compiler, since the accumulator holds the return
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value upon completion of the function call:
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JSR FUNC ;R = func()
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STA R
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Allowing a function call in susbsequent terms, however, requires
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extensive stack manipulation:
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whereas the equivalent C02 code generates much simpler machine code:
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Shift Operators
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----------------
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In standard C, the shift operators use the number of bits to shift as
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the operand. Since the 6502 shift and rotate instructions only shift
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one bit at a time, this would require the use of an index register and
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six to seven bytes of code
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expr code ;expr
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.LOOP LDY B ;>> B
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LSR
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DEY
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BNE .LOOP
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whereas a library function would require five bytes of code:
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SHIFTR: LSR ;A=Value to Shift
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DEY ;Y=Bits to Shift
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BNE SHIFTR
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RTS
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and each function call would use five bytes of code
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expr code ;shiftr(expr, B)
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LDY B
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JSR SHIFTR
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Following the philosophy that a operator should correspond to a single
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machine instruction, in C02 shifting is implemented as post-operators
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using the various available addressing modes:
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ASL S ;S<<
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LDX I ;T[I]>>
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LSR T,X
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ASL ;A<<
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Post-Operators and Pre-Operators
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--------------------------------
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Parsing for post-operators in a standalone expression is trivial, since
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that is the only time the relevant characters will only follow the operand.
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Implementing pre-operators on standalone expressions would be redundant
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since their would be no difference in the generated code.
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Parsing for post-operators and/or preoperators within an expression or
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evaluation, however, would complicate the detection of operators and
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comparators.
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In addition, the code generated from a post-operator or pre-operator
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withing an expression:
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DEC I ;R[--I]
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LDX I
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XXX R,X
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LDX I ;R[I++]
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XXX R,X
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INC I
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Is indentical to the code generated when using a standalone post-operator;
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DEC I ;I--
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LDX I ;R[I]
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XXX R,X
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LDX I ;R[I]
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XXX R,X
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INC I ;I++
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Assignments
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===========
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Assignment to a variable generates an STA instruction, using either absolute
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or indexed addressing mode:
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expr code ;R = expr
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STA R
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expr code ;R[2] = expr
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STA R+2
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expr code ;R[I] = expr
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LDX I
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STA R,I
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while assignment to an index register generates a transfer instruction:
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expr code ;Y = expr
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TAY
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expr code ;X = expr
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TAX
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and assignment to the Accumulator is simply a syntactical convenience:
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expr code ;A = expr
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Specific to C02 is the implied assignment, which also generates an STA:
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STA S ;S
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Allowing an expression as an array index in an assignment is problematic
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on an NMOS 6502 since the index expression will be evaluated prior to the
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expression being assigned to the array element and neither index register
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may be directly pushed or pulled from the stack.
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The addition of the PLX instruction to the 65C02 would allows this to be
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done using only two extra bytes of code for each variable assignment:
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indexp oode ;R[indexp] = expr
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PHA
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expr code
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PLX
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STA R,X
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expr oode ;R[expr], S[exps] = func()
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PHA
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exps code
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PHA
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JSR FUNC
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PLX
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STY S,X
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PLX
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STA R,X
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however, this would only work with the A and Y variables of a plural
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assignment.
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A workaround for the NMOS 6502 would require an extra five bytes of code
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indexp oode ;R[indexp] = expr
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PHA
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expr code
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TAY
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PLA
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TAX
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TYA
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STA R,X
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and the use of the Y register would limit it to the only the A variable
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of a plural assigment, whereas the equivalent C02 code would use an
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extra four to six bytes of code
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indexp code ;I = indexp;
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STA I
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expr code ;R[I] = expr
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LDX I
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STA R,X
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and works with all three variables of a plural assignment.
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Conditionals
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============
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Conditionals are separate and distinct from expressions, due to the fact
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that the comparison operators all set status flags which affect the various
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branch instructions:
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CMP DATA Normal Inverted
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Reg < Data BCC BCS
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Reg = Data BEQ BNE
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Reg ≥ Data BCS BCC
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Reg ≠ Data BNE BEQ
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The remaining operators can be implemented with CLC and SBC, but this will
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change the value in the accumulator.
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CLC:SBC DATA Normal Inverted
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Reg ≤ Data BCC BCS
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Reg > Data BCS BCC
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Or they could be implemented using multiple branch instructions. This would
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leave the value of the left side expression in the accumulator, but use one
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more byte of code and require and extra label.
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CMP DATA Normal Inverted
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Reg ≤ Data BEQ exec:BCC exec BNE exec:BCS exec
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Reg > Data BEQ skip:BCS exec BNE skip:BCC exec
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When compiling a comparison, the generated code will usually, but not
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always, branch when the condition is false, skipping to the end of the
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block of code following the comparison. In addition, the logical not
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operator will invert the comparison.
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By arranging the eight standard comparisons, along with evaluation of
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a term as true when non-zero, in this order:
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0 1 2 3 4 5 6 7
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!0 = < ≤ ≥ > ≠ 0
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the comparison can be inverted with a simple exclusive-or. For this
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reason, The ! operator is logical rather than bitwise and affects
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the result of the comparison rather than an individual expression
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or term within the expression.
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Standalone Expressions
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----------------------
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Flags Operators
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---------------
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Logical Operators
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-----------------
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Parsing the logical operators && and || is trivial if the preceding
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condition is a comparison or flag operation, since any expression
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evaluation is complete before the parse encounters the initial & or |
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character. For a standalone evaluation of an expression as true or
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false, however, the expression evaluator will mistake the initial
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character of the && or || as a bitwise operator. Differentiating
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the two would require changing to a look-ahead parser.
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One solution is to enclose require parentheses around each comparison
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when using logical operators, which is allowable in C syntax, but
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it's just as easy, and arguably cleaner looking, to use the words
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"and" and "or" instead. This is allowable in standard C by using
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the #define directive to alias "and" to "&&" and "or" to "||".
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The most efficient way to implement logical operators is to use shortcut
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evaluations.
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Under the normal circumstances, where the generated code branches when
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the condition is false, && can be implemented by evaluation the next
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comparison only in the event of the first condition being true.
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For ||, however, the following comparison will be evaluated only if the
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first comparison was false.
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LDA I ;IF (I<J
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CMP J
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BCS ENDIF
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LDA M ;&& M<>N)
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CMP N
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BEQ ENDIF
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LDA I ;IF (I<J
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CMP J
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BCC block
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LDA M ;|| M<>N)
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CMP N
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BEQ ENDIF
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block
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When chaining multiple && and/or || operators, the shortcut evaluation
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effectively make them right-associative.
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