kolibrios-gitea/programs/cmm/python/static/opcode.h

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#define buffer 1024
:struct VAR
{
dword data;
byte type;
dword length;
dword stack;
};
:dword build_map(dword count)
{
dword o = 0;
dword a1 = 0;
dword a2 = 0;
IF(count>8) o = arrayInit(count);
ELSE o = arrayInit(8);
WHILE(count)
{
a1 = popStack();
a2 = popStack();
SWITCH(DSBYTE[a2+4])
{
CASE PY_STR:
dictSet(#o,DSDWORD[a2],a1);
BREAK;
CASE PY_INT:
arraySet(#o,1,a1);
BREAK;
}
count--;
}
load_const(o,PY_DCT,0);
}
:void load_const(dword data,type,length)
{
DSDWORD[#RDATA] = data;
DSBYTE[#RDATA+4] = type;
DSDWORD[#RDATA+5] = length;
DSDWORD[#RDATA+9] = 0;
pushStack(#RDATA);
}
:void compare_op(byte cmd)
{
dword n = 0;
dword y = popStack();
dword x = popStack();
dword dx = 0;
dword dy = 0;
dword i = 0;
checkType(x,y);
IF(DSBYTE[x+4] == PY_STR)
{
IF(DSDWORD[x+5] == DSDWORD[y+5])
{
dx = DSDWORD[x];
dy = DSDWORD[y];
i = DSDWORD[x+5];
WHILE(i)
{
IF(DSBYTE[dx]!=DSBYTE[dy]) BREAK;
dx++;
dy++;
i--;
}
IF(!i) load_const(1,PY_BOOL,0);
ELSE load_const(0,PY_BOOL,0);
}
return;
}
IF(!cmd)IF(DSDWORD[x] == DSDWORD[y])
{
load_const(1,PY_BOOL,0);
return;
}
IF(cmd==1)IF(DSDWORD[x] != DSDWORD[y])
{
load_const(1,PY_BOOL,0);
return;
}
IF(cmd==2)IF(DSDWORD[x] >= DSDWORD[y])
{
load_const(1,PY_BOOL,0);
return;
}
IF(cmd==3)IF(DSDWORD[x] <= DSDWORD[y])
{
load_const(1,PY_BOOL,0);
return;
}
IF(cmd==4)IF(DSDWORD[x] > DSDWORD[y])
{
load_const(1,PY_BOOL,0);
return;
}
IF(cmd==5)IF(DSDWORD[x] < DSDWORD[y])
{
load_const(1,PY_BOOL,0);
return;
}
load_const(0,PY_BOOL,0);
}
:byte pop_jump_if(byte cmd)
{
dword x = 0;
x = popStack();
//test(DSDWORD[x+4],1);
SWITCH(DSBYTE[x+4])
{
CASE PY_INT:
CASE PY_BOOL:
IF(cmd){ IF (DSDWORD[x]) RETURN 1;}
IF(!cmd){ IF (!DSDWORD[x]) RETURN 1;}
BREAK;
CASE PY_STR:
IF(cmd){ IF (DSDWORD[x+5]) RETURN 1;}
IF(!cmd){ IF (!DSDWORD[x+5]) RETURN 1;}
BREAK;
}
RETURN 0;
}
:void pop_block()
{
stackLoop-=4;
}
:void unary_invert()
{
dword x = 0;
x = DSDWORD[stack-4];
EAX = DSDWORD[x];
$not eax;
DSDWORD[x] = EAX;
}
:void inplace(byte cmd)
{
dword buffer = 0;
dword length = 0;
Y = popStack();
X = DSDWORD[stack-4];
IF(cmd==PY_ADD) checkType(X,Y);
E = DSBYTE[X+4];
if(E==PY_STR)
{
A = DSDWORD[X+5];
IF(cmd==PY_ADD) B = DSDWORD[Y+5];
ELSE
{
C = DSDWORD[Y];
B = C*A;
}
length = A+B;
buffer = length+MEMBUF;
D = malloc(buffer);
IF(cmd==PY_ADD)
{
memcpy(D,DSDWORD[X],A);
memcpy(D+A,DSDWORD[Y],B);
}
ELSE IF(cmd==PY_MUL)
{
B = D;
E = DSDWORD[X];
WHILE(C)
{
memcpy(B,E,A);
B+=4;
C--;
}
}
DSDWORD[#RDATA] = D;
DSBYTE[#RDATA+4] = PY_STR;
DSDWORD[#RDATA+5] = length;
DSDWORD[#RDATA+9] = buffer;
pushStack(#RDATA);
return;
}
if(E==PY_INT)
{
switch(cmd)
{
case PY_ADD:
DSDWORD[X] += DSDWORD[Y];
break;
case PY_POW:
length = DSDWORD[Y];
D = DSDWORD[X];
DSDWORD[X] = 1;
WHILE(length) {DSDWORD[X]*=D; length--;}
break;
case PY_SUB:
DSDWORD[X] -= DSDWORD[Y];
break;
case PY_MUL:
DSDWORD[X] *= DSDWORD[Y];
break;
case PY_MOD:
DSDWORD[X] = DSDWORD[X]%DSDWORD[Y];
break;
case PY_XOR:
DSDWORD[X] ^= DSDWORD[Y];
break;
case PY_AND:
DSDWORD[X] &= DSDWORD[Y];
break;
case PY__OR:
DSDWORD[X] |= DSDWORD[Y];
break;
case PY_LSH:
DSDWORD[X] <<= DSDWORD[Y];
break;
case PY_RSH:
DSDWORD[X] >>= DSDWORD[Y];
break;
case PY_FDV:
DSDWORD[X] /= DSDWORD[Y];
break;
case PY_TDV:
DSDWORD[X] /= DSDWORD[Y];
break;
}
}
}
:void binary(byte cmd)
{
dword buffer = 0;
dword length = 0;
Y = popStack();
X = popStack();
IF(cmd==PY_ADD) checkType(X,Y);
E = DSBYTE[X+4];
if(E==PY_STR)
{
A = DSDWORD[X+5];
IF(cmd==PY_ADD) B = DSDWORD[Y+5];
ELSE
{
C = DSDWORD[Y];
B = C*A;
}
length = A+B;
buffer = length+MEMBUF;
D = malloc(buffer);
IF(cmd==PY_ADD)
{
memcpy(D,DSDWORD[X],A);
memcpy(D+A,DSDWORD[Y],B);
}
ELSE IF(cmd==PY_MUL)
{
B = D;
E = DSDWORD[X];
WHILE(C)
{
memcpy(B,E,A);
B+=4;
C--;
}
}
DSDWORD[#RDATA] = D;
DSBYTE[#RDATA+4] = PY_STR;
DSDWORD[#RDATA+5] = length;
DSDWORD[#RDATA+9] = buffer;
pushStack(#RDATA);
return;
}
if(E==PY_INT)
{
switch(cmd)
{
case PY_ADD:
A = DSDWORD[X] + DSDWORD[Y];
break;
case PY_POW:
length = DSDWORD[Y];
D = DSDWORD[X];
DSDWORD[Z] = 1;
WHILE(length) {A*=D; length--;}
break;
case PY_SUB:
A = DSDWORD[X] - DSDWORD[Y];
break;
case PY_MUL:
A = DSDWORD[X] * DSDWORD[Y];
break;
case PY_MOD:
A = DSDWORD[X] % DSDWORD[Y];
break;
case PY_XOR:
A = DSDWORD[X] ^ DSDWORD[Y];
break;
case PY_AND:
A = DSDWORD[X] & DSDWORD[Y];
break;
case PY__OR:
A = DSDWORD[X] | DSDWORD[Y];
break;
case PY_LSH:
A = DSDWORD[X] << DSDWORD[Y];
break;
case PY_RSH:
A = DSDWORD[X] >> DSDWORD[Y];
break;
case PY_FDV:
A = DSDWORD[X] / DSDWORD[Y];
break;
case PY_TDV:
A = DSDWORD[X] / DSDWORD[Y];
break;
}
load_const(A,PY_INT,0);
}
}
:byte del(dword v)
{
dword x = 0;
x = DSDWORD[v];
IF(x)
{
IF(DSDWORD[x+9]) free(DSDWORD[x]);
free(x);
DSDWORD[v] = 0;
RETURN 1;
}
RETURN 0;
}
:void build_class(dword count)
{
dword name = 0;
dword func = 0;
func = popFast();
name = popFast();
load_const(func,PY_CLS,0);
}
:void load_build_class()
{
load_const(#build_class,PY_FNC,0);
}
:void make_function()
{
stack-=4;
}
:void store_name(dword x)
{
dword tmp = 0;
dword stk = 0;
stk = popStack();
IF(!DSDWORD[x])
{
tmp = malloc(30);
memcpy(tmp,stk,30);
DSDWORD[x] = tmp;
return;
}
memcpy(DSDWORD[x],stk,30);
}
:void rot(dword x,y)
{
EAX = DSDWORD[stack-8];
DSDWORD[stack-8] = DSDWORD[stack-4];
DSDWORD[stack-4] = EAX;
}
:void build_tuple(dword len)
{
dword tuple = 0;
dword buf = 0;
dword l = 0;
l = len;
tuple = malloc(4*len+MEMBUF);
buf = tuple;
WHILE(len)
{
DSDWORD[buf] = popStack();
buf+=4;
len--;
}
load_const(tuple,PY_TPL,l);
}
:void unpack_sequence(dword len)
{
dword tuple = 0;
dword x = 0;
popStack();
tuple = DSDWORD[EAX];
WHILE(len)
{
pushStack(DSDWORD[tuple]);
tuple+=4;
len--;
}
}
:void rot_two()
{
rot(DSDWORD[stack-8],DSDWORD[stack-4]);
}
:void rot_three()
{
rot(DSDWORD[stack-12],DSDWORD[stack-4]);
rot(DSDWORD[stack-8],DSDWORD[stack-4]);
}
:void load_name(dword addr)
{
pushStack(addr);
}
:void load_global(dword addr)
{
pushStack(addr);
}
:dword strlen(dword txt)
{
dword i = 0;
i = txt;
WHILE(DSBYTE[i]) i++;
RETURN i - txt;
}
:dword hashString(dword x)
{
dword l = 0;
dword h = 0;
l = x;
WHILE(DSBYTE[x])
{
h+=DSBYTE[x];
h<<=1;
x++;
h/=x-l;
}
return h;
}
:void pop_top()
{
stack-=4;
}
:void load_fast(dword addr)
{
dword x = 0;
IF(!DSDWORD[addr])
{
x = popFast();
DSDWORD[addr] = x;
}
ELSE x = DSDWORD[addr];
pushStack(x);
}
:void call_function(dword arg)
{
dword count = 0;
dword func = 0;
byte type = 0;
dword stackRet = 0;
count = arg;
WHILE(count)
{
pushFast(popStack());
count--;
}
func = popStack();
//IF(DSBYTE[Z+4]!=PY_FNC) test("No function!",0);
type = DSBYTE[func+4];
func = DSDWORD[func];
IF(!func)
{
test1("Null function!",0);
pushStack(0);
return;
}
IF(type==PY_FNC)
{
stackRet = stack;
func(arg);
IF(stackRet == stack) load_const(0,PY_NONE,0);
}
ELSE IF(type==PY_CLS)
{
stackRet = stack;
func(arg);
IF(stackRet == stack) load_const(0,PY_NONE,0);
}
stackFast = beginStackFast;
}
:void call_method(dword arg)
{
dword count = 0;
dword func = 0;
byte type = 0;
dword stackRet = 0;
count = arg;
WHILE(count)
{
pushFast(popStack());
count--;
}
func = popStack();
//IF(DSBYTE[Z+4]!=PY_FNC) test("No function!",0);
type = DSBYTE[func+4];
func = DSDWORD[func];
IF(!func)
{
test1("Null function!",0);
pushStack(0);
return;
}
IF(type==PY_FNC)
{
stackRet = stack;
func(arg);
IF(stackRet == stack) load_const(0,PY_NONE,0);
}
ELSE IF(type==PY_CLS)
{
func(arg);
pushStack(EAX);
}
stackFast = beginStackFast;
}
:void load_method(dword name)
{
dword x = 0;
dword data = 0;
dword get = 0;
x = popStack();
data = DSDWORD[x];
get = dictGet(DSDWORD[data],name);
pushStack(get);
}
:void append(dword count)
{
dword x = 0;
dword y = 0;
x = popFast();
y = popFast();
test1(DSBYTE[x+4],1);
}
:void build_list(dword count)
{
dword n = 0;
dword mem = 0;
dword i = 0;
dword tmp = 0;
dword method = 0;
mem = malloc(count*4+MEMBUF);
i = count;
n = i*4+mem+4;
load_const(#append,PY_FNC,0);
dictSet(#method,"append",popStack());
DSDWORD[mem] = method;
WHILE(i)
{
n-=4;
tmp = malloc(30);
memcpy(tmp,popStack(),30);
DSDWORD[n] = tmp;
i--;
}
load_const(mem,PY_LST,count);
}
:dword store_fast()
{
return popStack();
}
:void binary_subscr()
{
dword x = 0;
dword y = 0;
dword l1 = 0;
dword l2 = 0;
dword tmp = 0;
dword ret = 0;
byte t = 0;
x = popStack();
y = popStack();
//IF(DSBYTE[x+4]!=PY_INT) error type;
l1 = DSDWORD[y+5];
t = DSBYTE[y+4];
IF(t==PY_LST)
{
IF(l1<=x) test1("error max list",0);
IF(0>l1) test1("error min list",0);
y = DSDWORD[y];
pushStack(DSDWORD[x*4+y]);
return;
}
IF(t==PY_DCT)
{
y = DSDWORD[y]; // data object
SWITCH(DSBYTE[x+4])
{
CASE PY_INT:
test1(DSDWORD[y],1);
x = arrayGet(DSDWORD[y],DSDWORD[x]);
BREAK;
CASE PY_STR:
x = dictGet(DSDWORD[y],DSDWORD[x]);
BREAK;
}
pushStack(x);
//test1(DSBYTE[x+4],1);
return;
}
IF(t==PY_STR)
{
x = DSDWORD[x];
IF (l1<=x)||(l1<0) test1("IndexError: string index out of range",0);
y = DSDWORD[y];
tmp = malloc(MEMBUF);
ret = malloc(30);
DSBYTE[tmp] = DSBYTE[x+y];
DSDWORD[ret] = tmp;
DSBYTE[ret+4] = PY_STR;
DSDWORD[ret+5] = 1;
DSDWORD[ret+9] = MEMBUF;
pushStack(ret);
return;
}
}
:void build_slice(dword count)
{
}
/*
:void call_function(dword arg)
{
dword x = 0;
dword c = arg;
dword o = 0;
dword v = 0;
WHILE(c)
{
o+=4;
popStack();
$push eax
c--;
}
$push arg
v = popStack();
IF(DSBYTE[v+4]!=PY_FNC) test("No function!",0);
v = DSDWORD[v];
IF(!v)
{
test(1,1);
pushStack(0);
return;
}
$call v
ESP+=o;
pushStack(EAX);
}
*/