gzdoom/src/xlat/xlat_parser.y
Christoph Oelckers 11e613f578 Merge branch 'master' into floatcvt
# Conflicts:
#	src/g_doom/a_revenant.cpp
2016-03-21 01:28:50 +01:00

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%token_prefix XLAT_
%token_type {FParseToken}
%token_destructor {} // just to avoid a compiler warning
%name XlatParse
%extra_argument { FParseContext *context }
%syntax_error { context->PrintError("syntax error");}
main ::= translation_unit.
translation_unit ::= . /* empty */
translation_unit ::= translation_unit external_declaration.
external_declaration ::= define_statement.
external_declaration ::= enum_statement.
external_declaration ::= linetype_declaration.
external_declaration ::= boom_declaration.
external_declaration ::= sector_declaration.
external_declaration ::= lineflag_declaration.
external_declaration ::= sector_bitmask.
external_declaration ::= maxlinespecial_def.
external_declaration ::= NOP.
%left OR.
%left XOR.
%left AND.
%left MINUS PLUS.
%left MULTIPLY DIVIDE MODULUS.
%left NEG.
%type expr {int}
expr(A) ::= NUM(B). { A = B.val; }
expr(A) ::= expr(B) PLUS expr(C). { A = B + C; }
expr(A) ::= expr(B) MINUS expr(C). { A = B - C; }
expr(A) ::= expr(B) MULTIPLY expr(C). { A = B * C; }
expr(A) ::= expr(B) DIVIDE expr(C). { if (C != 0) A = B / C; else context->PrintError("Division by zero"); }
expr(A) ::= expr(B) MODULUS expr(C). { if (C != 0) A = B % C; else context->PrintError("Division by zero"); }
expr(A) ::= expr(B) OR expr(C). { A = B | C; }
expr(A) ::= expr(B) AND expr(C). { A = B & C; }
expr(A) ::= expr(B) XOR expr(C). { A = B ^ C; }
expr(A) ::= MINUS expr(B). [NEG] { A = -B; }
expr(A) ::= LPAREN expr(B) RPAREN. { A = B; }
//==========================================================================
//
// define
//
//==========================================================================
define_statement ::= DEFINE SYM(A) LPAREN expr(B) RPAREN.
{
context->AddSym (A.sym, B);
}
//==========================================================================
//
// enum
//
//==========================================================================
enum_statement ::= enum_open enum_list RBRACE.
enum_open ::= ENUM LBRACE.
{
context->EnumVal = 0;
}
enum_list ::= . /* empty */
enum_list ::= single_enum.
enum_list ::= enum_list COMMA single_enum.
single_enum ::= SYM(A).
{
context->AddSym (A.sym, context->EnumVal++);
}
single_enum ::= SYM(A) EQUALS expr(B).
{
context->AddSym (A.sym, B);
context->EnumVal = B+1;
}
//==========================================================================
//
// standard linetype
//
//==========================================================================
%type linetype_exp {int}
linetype_exp(Z) ::= expr(A).
{
Z = static_cast<XlatParseContext *>(context)->DefiningLineType = A;
}
linetype_declaration ::= linetype_exp(linetype) EQUALS expr(flags) COMMA expr(special) LPAREN special_args(arg) RPAREN.
{
SimpleLineTranslations.SetVal(linetype,
FLineTrans(special&0xffff, flags+arg.addflags, arg.args[0], arg.args[1], arg.args[2], arg.args[3], arg.args[4]));
static_cast<XlatParseContext *>(context)->DefiningLineType = -1;
}
linetype_declaration ::= linetype_exp EQUALS expr COMMA SYM(S) LPAREN special_args RPAREN.
{
Printf ("%s, line %d: %s is undefined\n", context->SourceFile, context->SourceLine, S.sym);
static_cast<XlatParseContext *>(context)->DefiningLineType = -1;
}
%type exp_with_tag {int}
exp_with_tag(A) ::= NUM(B). { XlatExpressions.Push(B.val); A = XlatExpressions.Push(XEXP_Const); }
exp_with_tag(A) ::= TAG. { A = XlatExpressions.Push(XEXP_Tag); }
exp_with_tag(A) ::= exp_with_tag PLUS exp_with_tag. { A = XlatExpressions.Push(XEXP_Add); }
exp_with_tag(A) ::= exp_with_tag MINUS exp_with_tag. { A = XlatExpressions.Push(XEXP_Sub); }
exp_with_tag(A) ::= exp_with_tag MULTIPLY exp_with_tag. { A = XlatExpressions.Push(XEXP_Mul); }
exp_with_tag(A) ::= exp_with_tag DIVIDE exp_with_tag. { A = XlatExpressions.Push(XEXP_Div); }
exp_with_tag(A) ::= exp_with_tag MODULUS exp_with_tag. { A = XlatExpressions.Push(XEXP_Mod); }
exp_with_tag(A) ::= exp_with_tag OR exp_with_tag. { A = XlatExpressions.Push(XEXP_Or); }
exp_with_tag(A) ::= exp_with_tag AND exp_with_tag. { A = XlatExpressions.Push(XEXP_And); }
exp_with_tag(A) ::= exp_with_tag XOR exp_with_tag. { A = XlatExpressions.Push(XEXP_Xor); }
exp_with_tag(A) ::= MINUS exp_with_tag. [NEG] { A = XlatExpressions.Push(XEXP_Neg); }
exp_with_tag(A) ::= LPAREN exp_with_tag(B) RPAREN. { A = B; }
%type special_arg {SpecialArg}
special_arg(Z) ::= exp_with_tag(A).
{
if (XlatExpressions[A] == XEXP_Tag)
{ // Store tags directly
Z.arg = 0;
Z.argop = ARGOP_Tag;
XlatExpressions.Delete(A);
}
else
{ // Try and evaluate it. If it's a constant, store it and erase the
// expression. Otherwise, store the index to the expression. We make
// no attempt to simplify non-constant expressions.
FXlatExprState state;
int val;
const int *endpt;
int *xnode;
state.linetype = static_cast<XlatParseContext *>(context)->DefiningLineType;
state.tag = 0;
state.bIsConstant = true;
xnode = &XlatExpressions[A];
endpt = XlatExprEval[*xnode](&val, xnode, &state);
if (state.bIsConstant)
{
Z.arg = val;
Z.argop = ARGOP_Const;
endpt++;
assert(endpt >= &XlatExpressions[0]);
XlatExpressions.Resize((unsigned)(endpt - &XlatExpressions[0]));
}
else
{
Z.arg = A;
Z.argop = ARGOP_Expr;
}
}
}
%type multi_special_arg {SpecialArgs}
multi_special_arg(Z) ::= special_arg(A).
{
Z.addflags = A.argop << LINETRANS_TAGSHIFT;
Z.argcount = 1;
Z.args[0] = A.arg;
Z.args[1] = 0;
Z.args[2] = 0;
Z.args[3] = 0;
Z.args[4] = 0;
}
multi_special_arg(Z) ::= multi_special_arg(A) COMMA special_arg(B).
{
Z = A;
if (Z.argcount < LINETRANS_MAXARGS)
{
Z.addflags |= B.argop << (LINETRANS_TAGSHIFT + Z.argcount * TAGOP_NUMBITS);
Z.args[Z.argcount] = B.arg;
Z.argcount++;
}
else if (Z.argcount++ == LINETRANS_MAXARGS)
{
context->PrintError("Line special has too many arguments\n");
}
}
%type special_args {SpecialArgs}
special_args(Z) ::= . /* empty */
{
Z.addflags = 0;
Z.argcount = 0;
Z.args[0] = 0;
Z.args[1] = 0;
Z.args[2] = 0;
Z.args[3] = 0;
Z.args[4] = 0;
}
special_args(Z) ::= multi_special_arg(Z).
//==========================================================================
//
// boom generalized linetypes
//
//==========================================================================
%type list_val {ListFilter}
%type arg_list {MoreFilters *}
%type boom_args {ParseBoomArg}
%type boom_op {int}
%type boom_selector {int}
%type boom_line {FBoomArg}
%type boom_body {MoreLines *}
boom_declaration ::= LBRACKET expr(special) RBRACKET LPAREN expr(firsttype) COMMA expr(lasttype) RPAREN LBRACE boom_body(stores) RBRACE.
{
int i;
MoreLines *probe;
if (NumBoomish == MAX_BOOMISH)
{
MoreLines *probe = stores;
while (probe != NULL)
{
MoreLines *next = probe->next;
delete probe;
probe = next;
}
Printf ("%s, line %d: Too many BOOM translators\n", context->SourceFile, context->SourceLine);
}
else
{
Boomish[NumBoomish].FirstLinetype = firsttype;
Boomish[NumBoomish].LastLinetype = lasttype;
Boomish[NumBoomish].NewSpecial = special;
for (i = 0, probe = stores; probe != NULL; i++)
{
MoreLines *next = probe->next;
Boomish[NumBoomish].Args.Push(probe->arg);
delete probe;
probe = next;
}
NumBoomish++;
}
}
boom_body(A) ::= . /* empty */
{
A = NULL;
}
boom_body(A) ::= boom_line(B) boom_body(C).
{
A = new MoreLines;
A->next = C;
A->arg = B;
}
boom_line(A) ::= boom_selector(sel) boom_op(op) boom_args(args).
{
A.bOrExisting = (op == OR_EQUAL);
A.bUseConstant = (args.filters == NULL);
A.ArgNum = sel;
A.ConstantValue = args.constant;
A.AndValue = args.mask;
if (args.filters != NULL)
{
int i;
MoreFilters *probe;
for (i = 0, probe = args.filters; probe != NULL; i++)
{
MoreFilters *next = probe->next;
if (i < 15)
{
A.ResultFilter[i] = probe->filter.filter;
A.ResultValue[i] = probe->filter.value;
}
else if (i == 15)
{
context->PrintError ("Lists can only have 15 elements");
}
delete probe;
probe = next;
}
A.ListSize = i > 15 ? 15 : i;
}
}
boom_selector(A) ::= FLAGS. { A = 4; }
boom_selector(A) ::= ARG2. { A = 0; }
boom_selector(A) ::= ARG3. { A = 1; }
boom_selector(A) ::= ARG4. { A = 2; }
boom_selector(A) ::= ARG5. { A = 3; }
boom_op(A) ::= EQUALS. { A = '='; }
boom_op(A) ::= OR_EQUAL. { A = OR_EQUAL; }
boom_args(A) ::= expr(B).
{
A.constant = B;
A.filters = NULL;
}
boom_args(A) ::= expr(B) LBRACKET arg_list(C) RBRACKET.
{
A.mask = B;
A.filters = C;
}
arg_list(A) ::= list_val(B).
{
A = new MoreFilters;
A->next = NULL;
A->filter = B;
}
arg_list(A) ::= list_val(B) COMMA arg_list(C).
{
A = new MoreFilters;
A->next = C;
A->filter = B;
}
list_val(A) ::= expr(B) COLON expr(C).
{
A.filter = B;
A.value = C;
}
//==========================================================================
//
// max line special
//
//==========================================================================
maxlinespecial_def ::= MAXLINESPECIAL EQUALS expr(mx) SEMICOLON.
{
// Just kill all specials higher than the max.
// If the translator wants to redefine some later, just let it.
SimpleLineTranslations.Resize(mx+1);
}
//==========================================================================
//
// sector types
//
//==========================================================================
%type sector_op {int}
sector_declaration ::= SECTOR expr(from) EQUALS expr(to) SEMICOLON.
{
FSectorTrans tr(to, true);
SectorTranslations.SetVal(from, tr);
}
sector_declaration ::= SECTOR expr EQUALS SYM(sy) SEMICOLON.
{
Printf("Unknown constant '%s'\n", sy.sym);
}
sector_declaration ::= SECTOR expr(from) EQUALS expr(to) NOBITMASK SEMICOLON.
{
FSectorTrans tr(to, false);
SectorTranslations.SetVal(from, tr);
}
sector_bitmask ::= SECTOR BITMASK expr(mask) sector_op(op) expr(shift) SEMICOLON.
{
FSectorMask sm = { mask, op, shift};
SectorMasks.Push(sm);
}
sector_bitmask ::= SECTOR BITMASK expr(mask) SEMICOLON.
{
FSectorMask sm = { mask, 0, 0};
SectorMasks.Push(sm);
}
sector_bitmask ::= SECTOR BITMASK expr(mask) CLEAR SEMICOLON.
{
FSectorMask sm = { mask, 0, 1};
SectorMasks.Push(sm);
}
sector_op(A) ::= LSHASSIGN. { A = 1; }
sector_op(A) ::= RSHASSIGN. { A = -1; }
%type lineflag_op {int}
lineflag_declaration ::= LINEFLAG expr(from) EQUALS expr(to) SEMICOLON.
{
if (from >= 0 && from < 16)
{
LineFlagTranslations[from].newvalue = to;
LineFlagTranslations[from].ismask = false;
}
}
lineflag_declaration ::= LINEFLAG expr(from) AND expr(mask) SEMICOLON.
{
if (from >= 0 && from < 16)
{
LineFlagTranslations[from].newvalue = mask;
LineFlagTranslations[from].ismask = true;
}
}