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|
header {
import struct
import Utils
from UnicodeUtils import upack1
from ExcelMagic import *
_RVAdelta = {"R": 0, "V": 0x20, "A": 0x40}
_RVAdeltaRef = {"R": 0, "V": 0x20, "A": 0x40, "D": 0x20}
_RVAdeltaArea = {"R": 0, "V": 0x20, "A": 0x40, "D": 0}
class FormulaParseException(Exception):
"""
An exception indicating that a Formula could not be successfully parsed.
"""
}
header "ExcelFormulaParser.__init__" {
self.rpn = ""
self.sheet_references = []
self.xcall_references = []
}
options {
language = "Python";
}
class ExcelFormulaParser extends Parser;
options {
k = 2;
defaultErrorHandler = false;
buildAST = false;
}
tokens {
TRUE_CONST;
FALSE_CONST;
STR_CONST;
NUM_CONST;
INT_CONST;
FUNC_IF;
FUNC_CHOOSE;
NAME;
QUOTENAME;
EQ;
NE;
GT;
LT;
GE;
LE;
ADD;
SUB;
MUL;
DIV;
POWER;
PERCENT;
LP;
RP;
LB;
RB;
COLON;
COMMA;
SEMICOLON;
REF2D;
REF2D_R1C1;
BANG;
}
formula
: expr["V"]
;
expr[arg_type]
: // {print "\n**expr %s" % arg_type}
prec0_expr[arg_type]
(
(
EQ { op = struct.pack('B', ptgEQ) }
| NE { op = struct.pack('B', ptgNE) }
| GT { op = struct.pack('B', ptgGT) }
| LT { op = struct.pack('B', ptgLT) }
| GE { op = struct.pack('B', ptgGE) }
| LE { op = struct.pack('B', ptgLE) }
)
prec0_expr[arg_type] { self.rpn += op }
)*
;
prec0_expr[arg_type]
: prec1_expr[arg_type]
(
(
CONCAT { op = struct.pack('B', ptgConcat) }
)
prec1_expr[arg_type] { self.rpn += op }
)*
;
prec1_expr[arg_type]
: // {print "**prec1_expr1 %s" % arg_type}
prec2_expr[arg_type]
// {print "**prec1_expr2 %s" % arg_type}
(
(
ADD { op = struct.pack('B', ptgAdd) }
| SUB { op = struct.pack('B', ptgSub) }
)
// {print "**prec1_expr3 %s" % arg_type}
prec2_expr[arg_type]
{ self.rpn += op;
// print "**prec1_expr4 %s" % arg_type
}
)*
;
prec2_expr[arg_type]
: prec3_expr[arg_type]
(
(
MUL { op = struct.pack('B', ptgMul) }
| DIV { op = struct.pack('B', ptgDiv) }
)
prec3_expr[arg_type] { self.rpn += op }
)*
;
prec3_expr[arg_type]
: prec4_expr[arg_type]
(
(
POWER { op = struct.pack('B', ptgPower) }
)
prec4_expr[arg_type] { self.rpn += op }
)*
;
prec4_expr[arg_type]
: prec5_expr[arg_type]
(
PERCENT { self.rpn += struct.pack('B', ptgPercent) }
)?
;
prec5_expr[arg_type]
: primary[arg_type]
| SUB primary[arg_type] { self.rpn += struct.pack('B', ptgUminus) }
;
primary[arg_type]
: TRUE_CONST
{
self.rpn += struct.pack("2B", ptgBool, 1)
}
| FALSE_CONST
{
self.rpn += struct.pack("2B", ptgBool, 0)
}
| str_tok:STR_CONST
{
self.rpn += struct.pack("B", ptgStr) + upack1(str_tok.text[1:-1].replace("\"\"", "\""))
}
| int_tok:INT_CONST
{
// print "**int_const", int_tok.text
int_value = int(int_tok.text)
if int_value <= 65535:
self.rpn += struct.pack("<BH", ptgInt, int_value)
else:
self.rpn += struct.pack("<Bd", ptgNum, float(int_value))
}
| num_tok:NUM_CONST
{
self.rpn += struct.pack("<Bd", ptgNum, float(num_tok.text))
}
| ref2d_tok:REF2D
{
// print "**ref2d %s %s" % (ref2d_tok.text, arg_type)
r, c = Utils.cell_to_packed_rowcol(ref2d_tok.text)
ptg = ptgRefR + _RVAdeltaRef[arg_type]
self.rpn += struct.pack("<B2H", ptg, r, c)
}
| ref2d1_tok:REF2D COLON ref2d2_tok:REF2D
{
r1, c1 = Utils.cell_to_packed_rowcol(ref2d1_tok.text)
r2, c2 = Utils.cell_to_packed_rowcol(ref2d2_tok.text)
ptg = ptgAreaR + _RVAdeltaArea[arg_type]
self.rpn += struct.pack("<B4H", ptg, r1, r2, c1, c2)
}
| sheet1 = sheet
{
sheet2 = sheet1
}
( COLON sheet2 = sheet )? BANG ref3d_ref2d: REF2D
{
ptg = ptgRef3dR + _RVAdeltaRef[arg_type]
rpn_ref2d = ""
r1, c1 = Utils.cell_to_packed_rowcol(ref3d_ref2d.text)
rpn_ref2d = struct.pack("<3H", 0x0000, r1, c1)
}
( COLON ref3d_ref2d2: REF2D
{
ptg = ptgArea3dR + _RVAdeltaArea[arg_type]
r2, c2 = Utils.cell_to_packed_rowcol(ref3d_ref2d2.text)
rpn_ref2d = struct.pack("<5H", 0x0000, r1, r2, c1, c2)
}
)?
{
self.rpn += struct.pack("<B", ptg)
self.sheet_references.append((sheet1, sheet2, len(self.rpn)))
self.rpn += rpn_ref2d
}
| FUNC_IF
LP expr["V"] (SEMICOLON | COMMA)
{
self.rpn += struct.pack("<BBH", ptgAttr, 0x02, 0) // tAttrIf
pos0 = len(self.rpn) - 2
}
expr[arg_type] (SEMICOLON | COMMA)
{
self.rpn += struct.pack("<BBH", ptgAttr, 0x08, 0) // tAttrSkip
pos1 = len(self.rpn) - 2
self.rpn = self.rpn[:pos0] + struct.pack("<H", pos1-pos0) + self.rpn[pos0+2:]
}
expr[arg_type] RP
{
self.rpn += struct.pack("<BBH", ptgAttr, 0x08, 3) // tAttrSkip
self.rpn += struct.pack("<BBH", ptgFuncVarR, 3, 1) // 3 = nargs, 1 = IF func
pos2 = len(self.rpn)
self.rpn = self.rpn[:pos1] + struct.pack("<H", pos2-(pos1+2)-1) + self.rpn[pos1+2:]
}
| FUNC_CHOOSE
{
arg_type = "R"
rpn_chunks = []
}
LP expr["V"] // first argument (the selector)
{
rpn_start = len(self.rpn)
ref_markers = [len(self.sheet_references)]
}
(
(SEMICOLON | COMMA)
{ mark = len(self.rpn) }
(
expr[arg_type]
| { self.rpn += struct.pack("B", ptgMissArg) }
)
{
rpn_chunks.append(self.rpn[mark:])
ref_markers.append(len(self.sheet_references))
}
)*
RP
{
self.rpn = self.rpn[:rpn_start]
nc = len(rpn_chunks)
chunklens = [len(chunk) for chunk in rpn_chunks]
skiplens = [0] * nc
skiplens[-1] = 3
for ic in xrange(nc-1, 0, -1):
skiplens[ic-1] = skiplens[ic] + chunklens[ic] + 4
jump_pos = [2 * nc + 2]
for ic in xrange(nc):
jump_pos.append(jump_pos[-1] + chunklens[ic] + 4)
chunk_shift = 2 * nc + 6 // size of tAttrChoose
for ic in xrange(nc):
for refx in xrange(ref_markers[ic], ref_markers[ic+1]):
ref = self.sheet_references[refx]
self.sheet_references[refx] = (ref[0], ref[1], ref[2] + chunk_shift)
chunk_shift += 4 // size of tAttrSkip
choose_rpn = []
choose_rpn.append(struct.pack("<BBH", ptgAttr, 0x04, nc)) // 0x04 is tAttrChoose
choose_rpn.append(struct.pack("<%dH" % (nc+1), *jump_pos))
for ic in xrange(nc):
choose_rpn.append(rpn_chunks[ic])
choose_rpn.append(struct.pack("<BBH", ptgAttr, 0x08, skiplens[ic])) // 0x08 is tAttrSkip
choose_rpn.append(struct.pack("<BBH", ptgFuncVarV, nc+1, 100)) // 100 is CHOOSE fn
self.rpn += "".join(choose_rpn)
}
| name_tok:NAME
{
raise Exception("[formula] found unexpected NAME token (%r)" % name_tok.txt)
// #### TODO: handle references to defined names here
}
| func_tok:NAME
{
func_toku = func_tok.text.upper()
if func_toku in all_funcs_by_name:
(opcode,
min_argc,
max_argc,
func_type,
arg_type_str) = all_funcs_by_name[func_toku]
arg_type_list = list(arg_type_str)
else:
raise Exception("[formula] unknown function (%s)" % func_tok.text)
// print "**func_tok1 %s %s" % (func_toku, func_type)
xcall = opcode < 0
if xcall:
// The name of the add-in function is passed as the 1st arg
// of the hidden XCALL function
self.xcall_references.append((func_toku, len(self.rpn) + 1))
self.rpn += struct.pack("<BHHH",
ptgNameXR,
0xadde, // ##PATCHME## index to REF entry in EXTERNSHEET record
0xefbe, // ##PATCHME## one-based index to EXTERNNAME record
0x0000) // unused
}
LP arg_count = expr_list[arg_type_list, min_argc, max_argc] RP
{
if arg_count > max_argc or arg_count < min_argc:
raise Exception, "%d parameters for function: %s" % (arg_count, func_tok.text)
if xcall:
func_ptg = ptgFuncVarR + _RVAdelta[func_type]
self.rpn += struct.pack("<2BH", func_ptg, arg_count + 1, 255) // 255 is magic XCALL function
elif min_argc == max_argc:
func_ptg = ptgFuncR + _RVAdelta[func_type]
self.rpn += struct.pack("<BH", func_ptg, opcode)
elif arg_count == 1 and func_tok.text.upper() == "SUM":
self.rpn += struct.pack("<BBH", ptgAttr, 0x10, 0) // tAttrSum
else:
func_ptg = ptgFuncVarR + _RVAdelta[func_type]
self.rpn += struct.pack("<2BH", func_ptg, arg_count, opcode)
}
| LP expr[arg_type] RP
{
self.rpn += struct.pack("B", ptgParen)
}
;
expr_list[arg_type_list, min_argc, max_argc] returns [arg_cnt]
{
arg_cnt = 0
arg_type = arg_type_list[arg_cnt]
// print "**expr_list1[%d] req=%s" % (arg_cnt, arg_type)
}
: expr[arg_type] { arg_cnt += 1 }
(
{
if arg_cnt < len(arg_type_list):
arg_type = arg_type_list[arg_cnt]
else:
arg_type = arg_type_list[-1]
if arg_type == "+":
arg_type = arg_type_list[-2]
// print "**expr_list2[%d] req=%s" % (arg_cnt, arg_type)
}
(SEMICOLON | COMMA)
(
expr[arg_type]
| { self.rpn += struct.pack("B", ptgMissArg) }
)
{ arg_cnt += 1 }
)*
|
;
sheet returns[ref]
: sheet_ref_name: NAME
{ ref = sheet_ref_name.text }
| sheet_ref_int: INT_CONST
{ ref = sheet_ref_int.text }
| sheet_ref_quote: QUOTENAME
{ ref = sheet_ref_quote.text[1:-1].replace("''", "'") }
;
|
