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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-19 00:47:55 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-19 00:47:55 +0000
commit26a029d407be480d791972afb5975cf62c9360a6 (patch)
treef435a8308119effd964b339f76abb83a57c29483 /third_party/python/ply/example/BASIC/basinterp.py
parentInitial commit. (diff)
downloadfirefox-26a029d407be480d791972afb5975cf62c9360a6.tar.xz
firefox-26a029d407be480d791972afb5975cf62c9360a6.zip
Adding upstream version 124.0.1.upstream/124.0.1
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'third_party/python/ply/example/BASIC/basinterp.py')
-rw-r--r--third_party/python/ply/example/BASIC/basinterp.py496
1 files changed, 496 insertions, 0 deletions
diff --git a/third_party/python/ply/example/BASIC/basinterp.py b/third_party/python/ply/example/BASIC/basinterp.py
new file mode 100644
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+++ b/third_party/python/ply/example/BASIC/basinterp.py
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+# This file provides the runtime support for running a basic program
+# Assumes the program has been parsed using basparse.py
+
+import sys
+import math
+import random
+
+
+class BasicInterpreter:
+
+ # Initialize the interpreter. prog is a dictionary
+ # containing (line,statement) mappings
+ def __init__(self, prog):
+ self.prog = prog
+
+ self.functions = { # Built-in function table
+ 'SIN': lambda z: math.sin(self.eval(z)),
+ 'COS': lambda z: math.cos(self.eval(z)),
+ 'TAN': lambda z: math.tan(self.eval(z)),
+ 'ATN': lambda z: math.atan(self.eval(z)),
+ 'EXP': lambda z: math.exp(self.eval(z)),
+ 'ABS': lambda z: abs(self.eval(z)),
+ 'LOG': lambda z: math.log(self.eval(z)),
+ 'SQR': lambda z: math.sqrt(self.eval(z)),
+ 'INT': lambda z: int(self.eval(z)),
+ 'RND': lambda z: random.random()
+ }
+
+ # Collect all data statements
+ def collect_data(self):
+ self.data = []
+ for lineno in self.stat:
+ if self.prog[lineno][0] == 'DATA':
+ self.data = self.data + self.prog[lineno][1]
+ self.dc = 0 # Initialize the data counter
+
+ # Check for end statements
+ def check_end(self):
+ has_end = 0
+ for lineno in self.stat:
+ if self.prog[lineno][0] == 'END' and not has_end:
+ has_end = lineno
+ if not has_end:
+ print("NO END INSTRUCTION")
+ self.error = 1
+ return
+ if has_end != lineno:
+ print("END IS NOT LAST")
+ self.error = 1
+
+ # Check loops
+ def check_loops(self):
+ for pc in range(len(self.stat)):
+ lineno = self.stat[pc]
+ if self.prog[lineno][0] == 'FOR':
+ forinst = self.prog[lineno]
+ loopvar = forinst[1]
+ for i in range(pc + 1, len(self.stat)):
+ if self.prog[self.stat[i]][0] == 'NEXT':
+ nextvar = self.prog[self.stat[i]][1]
+ if nextvar != loopvar:
+ continue
+ self.loopend[pc] = i
+ break
+ else:
+ print("FOR WITHOUT NEXT AT LINE %s" % self.stat[pc])
+ self.error = 1
+
+ # Evaluate an expression
+ def eval(self, expr):
+ etype = expr[0]
+ if etype == 'NUM':
+ return expr[1]
+ elif etype == 'GROUP':
+ return self.eval(expr[1])
+ elif etype == 'UNARY':
+ if expr[1] == '-':
+ return -self.eval(expr[2])
+ elif etype == 'BINOP':
+ if expr[1] == '+':
+ return self.eval(expr[2]) + self.eval(expr[3])
+ elif expr[1] == '-':
+ return self.eval(expr[2]) - self.eval(expr[3])
+ elif expr[1] == '*':
+ return self.eval(expr[2]) * self.eval(expr[3])
+ elif expr[1] == '/':
+ return float(self.eval(expr[2])) / self.eval(expr[3])
+ elif expr[1] == '^':
+ return abs(self.eval(expr[2]))**self.eval(expr[3])
+ elif etype == 'VAR':
+ var, dim1, dim2 = expr[1]
+ if not dim1 and not dim2:
+ if var in self.vars:
+ return self.vars[var]
+ else:
+ print("UNDEFINED VARIABLE %s AT LINE %s" %
+ (var, self.stat[self.pc]))
+ raise RuntimeError
+ # May be a list lookup or a function evaluation
+ if dim1 and not dim2:
+ if var in self.functions:
+ # A function
+ return self.functions[var](dim1)
+ else:
+ # A list evaluation
+ if var in self.lists:
+ dim1val = self.eval(dim1)
+ if dim1val < 1 or dim1val > len(self.lists[var]):
+ print("LIST INDEX OUT OF BOUNDS AT LINE %s" %
+ self.stat[self.pc])
+ raise RuntimeError
+ return self.lists[var][dim1val - 1]
+ if dim1 and dim2:
+ if var in self.tables:
+ dim1val = self.eval(dim1)
+ dim2val = self.eval(dim2)
+ if dim1val < 1 or dim1val > len(self.tables[var]) or dim2val < 1 or dim2val > len(self.tables[var][0]):
+ print("TABLE INDEX OUT OUT BOUNDS AT LINE %s" %
+ self.stat[self.pc])
+ raise RuntimeError
+ return self.tables[var][dim1val - 1][dim2val - 1]
+ print("UNDEFINED VARIABLE %s AT LINE %s" %
+ (var, self.stat[self.pc]))
+ raise RuntimeError
+
+ # Evaluate a relational expression
+ def releval(self, expr):
+ etype = expr[1]
+ lhs = self.eval(expr[2])
+ rhs = self.eval(expr[3])
+ if etype == '<':
+ if lhs < rhs:
+ return 1
+ else:
+ return 0
+
+ elif etype == '<=':
+ if lhs <= rhs:
+ return 1
+ else:
+ return 0
+
+ elif etype == '>':
+ if lhs > rhs:
+ return 1
+ else:
+ return 0
+
+ elif etype == '>=':
+ if lhs >= rhs:
+ return 1
+ else:
+ return 0
+
+ elif etype == '=':
+ if lhs == rhs:
+ return 1
+ else:
+ return 0
+
+ elif etype == '<>':
+ if lhs != rhs:
+ return 1
+ else:
+ return 0
+
+ # Assignment
+ def assign(self, target, value):
+ var, dim1, dim2 = target
+ if not dim1 and not dim2:
+ self.vars[var] = self.eval(value)
+ elif dim1 and not dim2:
+ # List assignment
+ dim1val = self.eval(dim1)
+ if not var in self.lists:
+ self.lists[var] = [0] * 10
+
+ if dim1val > len(self.lists[var]):
+ print ("DIMENSION TOO LARGE AT LINE %s" % self.stat[self.pc])
+ raise RuntimeError
+ self.lists[var][dim1val - 1] = self.eval(value)
+ elif dim1 and dim2:
+ dim1val = self.eval(dim1)
+ dim2val = self.eval(dim2)
+ if not var in self.tables:
+ temp = [0] * 10
+ v = []
+ for i in range(10):
+ v.append(temp[:])
+ self.tables[var] = v
+ # Variable already exists
+ if dim1val > len(self.tables[var]) or dim2val > len(self.tables[var][0]):
+ print("DIMENSION TOO LARGE AT LINE %s" % self.stat[self.pc])
+ raise RuntimeError
+ self.tables[var][dim1val - 1][dim2val - 1] = self.eval(value)
+
+ # Change the current line number
+ def goto(self, linenum):
+ if not linenum in self.prog:
+ print("UNDEFINED LINE NUMBER %d AT LINE %d" %
+ (linenum, self.stat[self.pc]))
+ raise RuntimeError
+ self.pc = self.stat.index(linenum)
+
+ # Run it
+ def run(self):
+ self.vars = {} # All variables
+ self.lists = {} # List variables
+ self.tables = {} # Tables
+ self.loops = [] # Currently active loops
+ self.loopend = {} # Mapping saying where loops end
+ self.gosub = None # Gosub return point (if any)
+ self.error = 0 # Indicates program error
+
+ self.stat = list(self.prog) # Ordered list of all line numbers
+ self.stat.sort()
+ self.pc = 0 # Current program counter
+
+ # Processing prior to running
+
+ self.collect_data() # Collect all of the data statements
+ self.check_end()
+ self.check_loops()
+
+ if self.error:
+ raise RuntimeError
+
+ while 1:
+ line = self.stat[self.pc]
+ instr = self.prog[line]
+
+ op = instr[0]
+
+ # END and STOP statements
+ if op == 'END' or op == 'STOP':
+ break # We're done
+
+ # GOTO statement
+ elif op == 'GOTO':
+ newline = instr[1]
+ self.goto(newline)
+ continue
+
+ # PRINT statement
+ elif op == 'PRINT':
+ plist = instr[1]
+ out = ""
+ for label, val in plist:
+ if out:
+ out += ' ' * (15 - (len(out) % 15))
+ out += label
+ if val:
+ if label:
+ out += " "
+ eval = self.eval(val)
+ out += str(eval)
+ sys.stdout.write(out)
+ end = instr[2]
+ if not (end == ',' or end == ';'):
+ sys.stdout.write("\n")
+ if end == ',':
+ sys.stdout.write(" " * (15 - (len(out) % 15)))
+ if end == ';':
+ sys.stdout.write(" " * (3 - (len(out) % 3)))
+
+ # LET statement
+ elif op == 'LET':
+ target = instr[1]
+ value = instr[2]
+ self.assign(target, value)
+
+ # READ statement
+ elif op == 'READ':
+ for target in instr[1]:
+ if self.dc < len(self.data):
+ value = ('NUM', self.data[self.dc])
+ self.assign(target, value)
+ self.dc += 1
+ else:
+ # No more data. Program ends
+ return
+ elif op == 'IF':
+ relop = instr[1]
+ newline = instr[2]
+ if (self.releval(relop)):
+ self.goto(newline)
+ continue
+
+ elif op == 'FOR':
+ loopvar = instr[1]
+ initval = instr[2]
+ finval = instr[3]
+ stepval = instr[4]
+
+ # Check to see if this is a new loop
+ if not self.loops or self.loops[-1][0] != self.pc:
+ # Looks like a new loop. Make the initial assignment
+ newvalue = initval
+ self.assign((loopvar, None, None), initval)
+ if not stepval:
+ stepval = ('NUM', 1)
+ stepval = self.eval(stepval) # Evaluate step here
+ self.loops.append((self.pc, stepval))
+ else:
+ # It's a repeat of the previous loop
+ # Update the value of the loop variable according to the
+ # step
+ stepval = ('NUM', self.loops[-1][1])
+ newvalue = (
+ 'BINOP', '+', ('VAR', (loopvar, None, None)), stepval)
+
+ if self.loops[-1][1] < 0:
+ relop = '>='
+ else:
+ relop = '<='
+ if not self.releval(('RELOP', relop, newvalue, finval)):
+ # Loop is done. Jump to the NEXT
+ self.pc = self.loopend[self.pc]
+ self.loops.pop()
+ else:
+ self.assign((loopvar, None, None), newvalue)
+
+ elif op == 'NEXT':
+ if not self.loops:
+ print("NEXT WITHOUT FOR AT LINE %s" % line)
+ return
+
+ nextvar = instr[1]
+ self.pc = self.loops[-1][0]
+ loopinst = self.prog[self.stat[self.pc]]
+ forvar = loopinst[1]
+ if nextvar != forvar:
+ print("NEXT DOESN'T MATCH FOR AT LINE %s" % line)
+ return
+ continue
+ elif op == 'GOSUB':
+ newline = instr[1]
+ if self.gosub:
+ print("ALREADY IN A SUBROUTINE AT LINE %s" % line)
+ return
+ self.gosub = self.stat[self.pc]
+ self.goto(newline)
+ continue
+
+ elif op == 'RETURN':
+ if not self.gosub:
+ print("RETURN WITHOUT A GOSUB AT LINE %s" % line)
+ return
+ self.goto(self.gosub)
+ self.gosub = None
+
+ elif op == 'FUNC':
+ fname = instr[1]
+ pname = instr[2]
+ expr = instr[3]
+
+ def eval_func(pvalue, name=pname, self=self, expr=expr):
+ self.assign((pname, None, None), pvalue)
+ return self.eval(expr)
+ self.functions[fname] = eval_func
+
+ elif op == 'DIM':
+ for vname, x, y in instr[1]:
+ if y == 0:
+ # Single dimension variable
+ self.lists[vname] = [0] * x
+ else:
+ # Double dimension variable
+ temp = [0] * y
+ v = []
+ for i in range(x):
+ v.append(temp[:])
+ self.tables[vname] = v
+
+ self.pc += 1
+
+ # Utility functions for program listing
+ def expr_str(self, expr):
+ etype = expr[0]
+ if etype == 'NUM':
+ return str(expr[1])
+ elif etype == 'GROUP':
+ return "(%s)" % self.expr_str(expr[1])
+ elif etype == 'UNARY':
+ if expr[1] == '-':
+ return "-" + str(expr[2])
+ elif etype == 'BINOP':
+ return "%s %s %s" % (self.expr_str(expr[2]), expr[1], self.expr_str(expr[3]))
+ elif etype == 'VAR':
+ return self.var_str(expr[1])
+
+ def relexpr_str(self, expr):
+ return "%s %s %s" % (self.expr_str(expr[2]), expr[1], self.expr_str(expr[3]))
+
+ def var_str(self, var):
+ varname, dim1, dim2 = var
+ if not dim1 and not dim2:
+ return varname
+ if dim1 and not dim2:
+ return "%s(%s)" % (varname, self.expr_str(dim1))
+ return "%s(%s,%s)" % (varname, self.expr_str(dim1), self.expr_str(dim2))
+
+ # Create a program listing
+ def list(self):
+ stat = list(self.prog) # Ordered list of all line numbers
+ stat.sort()
+ for line in stat:
+ instr = self.prog[line]
+ op = instr[0]
+ if op in ['END', 'STOP', 'RETURN']:
+ print("%s %s" % (line, op))
+ continue
+ elif op == 'REM':
+ print("%s %s" % (line, instr[1]))
+ elif op == 'PRINT':
+ _out = "%s %s " % (line, op)
+ first = 1
+ for p in instr[1]:
+ if not first:
+ _out += ", "
+ if p[0] and p[1]:
+ _out += '"%s"%s' % (p[0], self.expr_str(p[1]))
+ elif p[1]:
+ _out += self.expr_str(p[1])
+ else:
+ _out += '"%s"' % (p[0],)
+ first = 0
+ if instr[2]:
+ _out += instr[2]
+ print(_out)
+ elif op == 'LET':
+ print("%s LET %s = %s" %
+ (line, self.var_str(instr[1]), self.expr_str(instr[2])))
+ elif op == 'READ':
+ _out = "%s READ " % line
+ first = 1
+ for r in instr[1]:
+ if not first:
+ _out += ","
+ _out += self.var_str(r)
+ first = 0
+ print(_out)
+ elif op == 'IF':
+ print("%s IF %s THEN %d" %
+ (line, self.relexpr_str(instr[1]), instr[2]))
+ elif op == 'GOTO' or op == 'GOSUB':
+ print("%s %s %s" % (line, op, instr[1]))
+ elif op == 'FOR':
+ _out = "%s FOR %s = %s TO %s" % (
+ line, instr[1], self.expr_str(instr[2]), self.expr_str(instr[3]))
+ if instr[4]:
+ _out += " STEP %s" % (self.expr_str(instr[4]))
+ print(_out)
+ elif op == 'NEXT':
+ print("%s NEXT %s" % (line, instr[1]))
+ elif op == 'FUNC':
+ print("%s DEF %s(%s) = %s" %
+ (line, instr[1], instr[2], self.expr_str(instr[3])))
+ elif op == 'DIM':
+ _out = "%s DIM " % line
+ first = 1
+ for vname, x, y in instr[1]:
+ if not first:
+ _out += ","
+ first = 0
+ if y == 0:
+ _out += "%s(%d)" % (vname, x)
+ else:
+ _out += "%s(%d,%d)" % (vname, x, y)
+
+ print(_out)
+ elif op == 'DATA':
+ _out = "%s DATA " % line
+ first = 1
+ for v in instr[1]:
+ if not first:
+ _out += ","
+ first = 0
+ _out += v
+ print(_out)
+
+ # Erase the current program
+ def new(self):
+ self.prog = {}
+
+ # Insert statements
+ def add_statements(self, prog):
+ for line, stat in prog.items():
+ self.prog[line] = stat
+
+ # Delete a statement
+ def del_line(self, lineno):
+ try:
+ del self.prog[lineno]
+ except KeyError:
+ pass