mirror of
https://github.com/irmen/prog8.git
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261 lines
12 KiB
Python
261 lines
12 KiB
Python
"""
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Programming Language for 6502/6510 microprocessors, codename 'Sick'
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This is the code generator for variable declarations and initialization.
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Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0
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"""
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from collections import defaultdict
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from typing import Dict, List, Callable, Any
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from ..plyparse import Block, VarType, VarDef
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from ..datatypes import DataType, STRING_DATATYPES
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from . import to_hex, to_mflpt5, CodeError
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def generate_block_init(out: Callable, block: Block) -> None:
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# generate the block initializer
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# @todo add a block initializer subroutine that can contain custom reset/init code? (static initializer)
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# @todo will be called at program start automatically, so there's no risk of forgetting to call it manually
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def _memset(varname: str, value: int, size: int) -> None:
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if size > 6:
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out("\vlda #<" + varname)
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out("\vsta il65_lib.SCRATCH_ZPWORD1")
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out("\vlda #>" + varname)
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out("\vsta il65_lib.SCRATCH_ZPWORD1+1")
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out("\vlda #" + to_hex(value))
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out("\vldx #<" + to_hex(size))
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out("\vldy #>" + to_hex(size))
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out("\vjsr il65_lib.memset")
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else:
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out("\vlda #" + to_hex(value))
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for i in range(size):
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out("\vsta {:s}+{:d}".format(varname, i))
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def _memsetw(varname: str, value: int, size: int) -> None:
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if size > 4:
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out("\vlda #<" + varname)
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out("\vsta il65_lib.SCRATCH_ZPWORD1")
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out("\vlda #>" + varname)
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out("\vsta il65_lib.SCRATCH_ZPWORD1+1")
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out("\vlda #<" + to_hex(size))
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out("\vsta il65_lib.SCRATCH_ZPWORD2")
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out("\vlda #>" + to_hex(size))
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out("\vsta il65_lib.SCRATCH_ZPWORD2+1")
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out("\vlda #<" + to_hex(value))
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out("\vldx #>" + to_hex(value))
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out("\vjsr il65_lib.memsetw")
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else:
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out("\vlda #<" + to_hex(value))
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out("\vldy #>" + to_hex(value))
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for i in range(size):
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out("\vsta {:s}+{:d}".format(varname, i * 2))
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out("\vsty {:s}+{:d}".format(varname, i * 2 + 1))
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out("_il65_init_block\v; (re)set vars to initial values")
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float_inits = {}
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prev_value_a, prev_value_x = None, None
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vars_by_datatype = defaultdict(list) # type: Dict[DataType, List[VarDef]]
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for vardef in block.scope.filter_nodes(VarDef):
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if vardef.vartype == VarType.VAR:
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vars_by_datatype[vardef.datatype].append(vardef)
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for bytevar in sorted(vars_by_datatype[DataType.BYTE], key=lambda vd: vd.value):
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assert type(bytevar.value) is int
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if bytevar.value != prev_value_a:
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out("\vlda #${:02x}".format(bytevar.value))
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prev_value_a = bytevar.value
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out("\vsta {:s}".format(bytevar.name))
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for wordvar in sorted(vars_by_datatype[DataType.WORD], key=lambda vd: vd.value):
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assert type(wordvar.value) is int
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v_hi, v_lo = divmod(wordvar.value, 256)
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if v_hi != prev_value_a:
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out("\vlda #${:02x}".format(v_hi))
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prev_value_a = v_hi
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if v_lo != prev_value_x:
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out("\vldx #${:02x}".format(v_lo))
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prev_value_x = v_lo
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out("\vsta {:s}".format(wordvar.name))
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out("\vstx {:s}+1".format(wordvar.name))
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for floatvar in vars_by_datatype[DataType.FLOAT]:
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assert isinstance(floatvar.value, (int, float))
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fpbytes = to_mflpt5(floatvar.value) # type: ignore
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float_inits[floatvar.name] = (floatvar.name, fpbytes, floatvar.value)
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for arrayvar in vars_by_datatype[DataType.BYTEARRAY]:
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assert type(arrayvar.value) is int
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_memset(arrayvar.name, arrayvar.value, arrayvar.size[0])
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for arrayvar in vars_by_datatype[DataType.WORDARRAY]:
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assert type(arrayvar.value) is int
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_memsetw(arrayvar.name, arrayvar.value, arrayvar.size[0])
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for arrayvar in vars_by_datatype[DataType.MATRIX]:
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assert type(arrayvar.value) is int
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_memset(arrayvar.name, arrayvar.value, arrayvar.size[0] * arrayvar.size[1])
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if float_inits:
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out("\vldx #4")
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out("-")
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for varname, (vname, b, fv) in sorted(float_inits.items()):
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out("\vlda _init_float_{:s},x".format(varname))
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out("\vsta {:s},x".format(vname))
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out("\vdex")
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out("\vbpl -")
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out("\vrts\n")
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for varname, (vname, fpbytes, fpvalue) in sorted(float_inits.items()):
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out("_init_float_{:s}\t\t.byte ${:02x}, ${:02x}, ${:02x}, ${:02x}, ${:02x}\t; {}".format(varname, *fpbytes, fpvalue))
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all_string_vars = []
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for svtype in STRING_DATATYPES:
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all_string_vars.extend(vars_by_datatype[svtype])
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for strvar in all_string_vars:
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# string vars are considered to be a constant, and are statically initialized.
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_generate_string_var(out, strvar)
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out("")
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def generate_block_vars(out: Callable, block: Block, zeropage: bool=False) -> None:
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# Generate the block variable storage.
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# The memory bytes of the allocated variables is set to zero (so it compresses very well),
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# their actual starting values are set by the block init code.
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vars_by_vartype = defaultdict(list) # type: Dict[VarType, List[VarDef]]
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for vardef in block.scope.filter_nodes(VarDef):
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vars_by_vartype[vardef.vartype].append(vardef)
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out("; constants")
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for vardef in vars_by_vartype.get(VarType.CONST, []):
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if vardef.datatype == DataType.FLOAT:
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out("\v{:s} = {}".format(vardef.name, _numeric_value_str(vardef.value)))
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elif vardef.datatype in (DataType.BYTE, DataType.WORD):
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out("\v{:s} = {:s}".format(vardef.name, _numeric_value_str(vardef.value, True)))
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elif vardef.datatype.isstring():
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# a const string is just a string variable in the generated assembly
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_generate_string_var(out, vardef)
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else:
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raise CodeError("invalid const type", vardef)
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out("; memory mapped variables")
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for vardef in vars_by_vartype.get(VarType.MEMORY, []):
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# create a definition for variables at a specific place in memory (memory-mapped)
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if vardef.datatype.isnumeric():
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assert vardef.size == [1]
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out("\v{:s} = {:s}\t; {:s}".format(vardef.name, to_hex(vardef.value), vardef.datatype.name.lower()))
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elif vardef.datatype == DataType.BYTEARRAY:
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assert len(vardef.size) == 1
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out("\v{:s} = {:s}\t; array of {:d} bytes".format(vardef.name, to_hex(vardef.value), vardef.size[0]))
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elif vardef.datatype == DataType.WORDARRAY:
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assert len(vardef.size) == 1
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out("\v{:s} = {:s}\t; array of {:d} words".format(vardef.name, to_hex(vardef.value), vardef.size[0]))
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elif vardef.datatype == DataType.MATRIX:
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assert len(vardef.size) in (2, 3)
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if len(vardef.size) == 2:
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comment = "matrix of {:d} by {:d} = {:d} bytes".format(vardef.size[0], vardef.size[1], vardef.size[0]*vardef.size[1])
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elif len(vardef.size) == 3:
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comment = "matrix of {:d} by {:d}, interleave {:d}".format(vardef.size[0], vardef.size[1], vardef.size[2])
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else:
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raise CodeError("matrix size should be 2 or 3 numbers")
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out("\v{:s} = {:s}\t; {:s}".format(vardef.name, to_hex(vardef.value), comment))
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else:
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raise CodeError("invalid var type")
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out("; normal variables - initial values will be set by init code")
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if zeropage:
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# zeropage uses the zp_address we've allocated, instead of allocating memory here
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for vardef in vars_by_vartype.get(VarType.VAR, []):
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assert vardef.zp_address is not None
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if vardef.datatype.isstring():
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raise CodeError("cannot put strings in the zeropage", vardef.sourceref)
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if vardef.datatype.isarray():
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size_str = "size " + str(vardef.size)
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else:
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size_str = ""
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out("\v{:s} = {:s}\t; {:s} {:s}".format(vardef.name, to_hex(vardef.zp_address), vardef.datatype.name.lower(), size_str))
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else:
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# create definitions for the variables that takes up empty space and will be initialized at startup
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string_vars = []
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for vardef in vars_by_vartype.get(VarType.VAR, []):
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if vardef.datatype.isnumeric():
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assert vardef.size == [1]
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if vardef.datatype == DataType.BYTE:
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out("{:s}\v.byte ?".format(vardef.name))
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elif vardef.datatype == DataType.WORD:
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out("{:s}\v.word ?".format(vardef.name))
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elif vardef.datatype == DataType.FLOAT:
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out("{:s}\v.fill 5\t\t; float".format(vardef.name))
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else:
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raise CodeError("weird datatype")
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elif vardef.datatype in (DataType.BYTEARRAY, DataType.WORDARRAY):
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assert len(vardef.size) == 1
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if vardef.datatype == DataType.BYTEARRAY:
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out("{:s}\v.fill {:d}\t\t; bytearray".format(vardef.name, vardef.size[0]))
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elif vardef.datatype == DataType.WORDARRAY:
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out("{:s}\v.fill {:d}*2\t\t; wordarray".format(vardef.name, vardef.size[0]))
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else:
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raise CodeError("invalid datatype", vardef.datatype)
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elif vardef.datatype == DataType.MATRIX:
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assert len(vardef.size) == 2
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out("{:s}\v.fill {:d}\t\t; matrix {:d}*{:d} bytes"
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.format(vardef.name, vardef.size[0] * vardef.size[1], vardef.size[0], vardef.size[1]))
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elif vardef.datatype.isstring():
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string_vars.append(vardef)
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else:
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raise CodeError("unknown variable type " + str(vardef.datatype))
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# string vars are considered to be a constant, and are not re-initialized.
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out("")
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def _generate_string_var(out: Callable, vardef: VarDef) -> None:
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if vardef.datatype == DataType.STRING:
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# 0-terminated string
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out("{:s}\n\v.null {:s}".format(vardef.name, _format_string(str(vardef.value))))
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elif vardef.datatype == DataType.STRING_P:
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# pascal string
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out("{:s}\n\v.ptext {:s}".format(vardef.name, _format_string(str(vardef.value))))
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elif vardef.datatype == DataType.STRING_S:
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# 0-terminated string in screencode encoding
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out(".enc 'screen'")
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out("{:s}\n\v.null {:s}".format(vardef.name, _format_string(str(vardef.value), True)))
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out(".enc 'none'")
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elif vardef.datatype == DataType.STRING_PS:
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# 0-terminated pascal string in screencode encoding
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out(".enc 'screen'")
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out("{:s}n\v.ptext {:s}".format(vardef.name, _format_string(str(vardef.value), True)))
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out(".enc 'none'")
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def _format_string(value: str, screencodes: bool = False) -> str:
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if len(value) == 1 and screencodes:
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if value[0].isprintable() and ord(value[0]) < 128:
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return "'{:s}'".format(value[0])
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else:
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return str(ord(value[0]))
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result = '"'
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for char in value:
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if char in "{}":
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result += '", {:d}, "'.format(ord(char))
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elif char.isprintable() and ord(char) < 128:
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result += char
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else:
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if screencodes:
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result += '", {:d}, "'.format(ord(char))
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else:
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if char == '\f':
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result += "{clear}"
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elif char == '\b':
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result += "{delete}"
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elif char == '\n':
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result += "{cr}"
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elif char == '\r':
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result += "{down}"
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elif char == '\t':
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result += "{tab}"
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else:
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result += '", {:d}, "'.format(ord(char))
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return result + '"'
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def _numeric_value_str(value: Any, as_hex: bool=False) -> str:
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if isinstance(value, bool):
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return "1" if value else "0"
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if type(value) is int:
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if as_hex:
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return to_hex(value)
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return str(value)
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if isinstance(value, (int, float)):
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if as_hex:
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raise TypeError("cannot output float as hex")
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return str(value)
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raise TypeError("no numeric representation possible", value)
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