Mercurial > lcfOS
view python/target/arminstructions.py @ 300:158068af716c
yafm
author | Windel Bouwman |
---|---|
date | Tue, 03 Dec 2013 18:00:22 +0100 |
parents | 534b94b40aa8 |
children | 0615b5308710 |
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import struct from asmnodes import ASymbol, AInstruction, ANumber, AUnop, ABinop from .basetarget import Register, Instruction, Target, Label, LabelRef from .basetarget import Imm32, Imm8, Imm7, Imm3 def u16(h): return struct.pack('<H', h) def u32(x): return struct.pack('<I', x) # Operands: class ArmRegister(Register): def __init__(self, num, name): super().__init__(name) self.num = num def __repr__(self): return self.name @classmethod def Create(cls, vop): if type(vop) is ASymbol: name = vop.name regs = {} for r in registers: regs[r.name] = r if name in regs: r = regs[name] if isinstance(r, cls): return r class Reg8Op(ArmRegister): pass class Reg16Op(ArmRegister): pass R0 = Reg8Op(0, 'r0') R1 = Reg8Op(1, 'r1') R2 = Reg8Op(2, 'r2') R3 = Reg8Op(3, 'r3') R4 = Reg8Op(4, 'r4') R5 = Reg8Op(5, 'r5') R6 = Reg8Op(6, 'r6') R7 = Reg8Op(7, 'r7') # Other registers: # TODO SP = ArmRegister(13, 'sp') LR = ArmRegister(14, 'lr') PC = ArmRegister(15, 'pc') registers = [R0, R1, R2, R3, R4, R5, R6, R7, SP, LR, PC] class RegSpOp: @classmethod def Create(cls, vop): if type(vop) is ASymbol: if vop.name.lower() == 'sp': return cls() def getRegNum(n): for r in registers: if r.num == n: return r def getRegisterRange(n1, n2): regs = [] if n1.num < n2.num: for n in range(n1.num, n2.num + 1): r = getRegNum(n) assert r regs.append(r) return regs def isRegOffset(regname, x, y): if type(x) is ASymbol and type(y) is ANumber and x.name.upper() == regname: return y.number elif type(y) is ASymbol and type(x) is ANumber and y.name.upper() == regname: return x.number class MemRegXRel: def __init__(self, offset): assert offset % 4 == 0 self.offset = offset def __repr__(self): return '[{}, #{}]'.format(self.regname, self.offset) @classmethod def Create(cls, vop): if type(vop) is AUnop and vop.operation == '[]' and type(vop.arg) is ABinop and vop.arg.op == '+': vop = vop.arg # descent offset = isRegOffset(cls.regname, vop.arg1, vop.arg2) if type(offset) is int: if offset % 4 == 0: offset = vop.arg2.number return cls(offset) elif type(vop) is ASymbol and vop.name.upper() == self.regname: return cls(0) class MemSpRel(MemRegXRel): regname = 'SP' class MemR8Rel: def __init__(self, basereg, offset): assert type(basereg) is Reg8Op assert type(offset) is int self.basereg = basereg self.offset = offset def __repr__(self): return '[{}, #{}]'.format(self.basereg, self.offset) @classmethod def Create(cls, vop): if type(vop) is AUnop and vop.operation == '[]': vop = vop.arg # descent if type(vop) is ABinop: if vop.op == '+' and type(vop.arg1) is ASymbol and type(vop.arg2) is ANumber: offset = vop.arg2.number if offset > 120: return basereg = Reg8Op.Create(vop.arg1) if not basereg: return else: return elif type(vop) is ASymbol: offset = 0 basereg = Reg8Op.Create(vop) if not basereg: return else: return return cls(getRegNum(basereg.num), offset) class RegisterSet: def __init__(self, regs): assert type(regs) is set self.regs = regs def __repr__(self): return ','.join([str(r) for r in self.regs]) @classmethod def Create(cls, vop): assert type(vop) is AUnop and vop.operation == '{}' assert type(vop.arg) is list regs = set() for arg in vop.arg: if type(arg) is ASymbol: reg = ArmRegister.Create(arg) if not reg: return regs.add(reg) elif type(arg) is ABinop and arg.op == '-': reg1 = ArmRegister.Create(arg.arg1) reg2 = ArmRegister.Create(arg.arg2) if not reg1: return if not reg2: return for r in getRegisterRange(reg1, reg2): regs.add(r) else: raise Exception('Cannot be') return cls(regs) def registerNumbers(self): return [r.num for r in self.regs] # Instructions: class ArmInstruction(Instruction): pass allins = [] def instruction(i): allins.append(i) return i @instruction class Dcd(ArmInstruction): mnemonic = 'dcd' operands = (Imm32,) def __init__(self, expr): if isinstance(expr, Imm32): self.expr = expr.imm self.label = None elif isinstance(expr, LabelRef): self.expr = 0 self.label = expr elif isinstance(expr, int): self.expr = expr self.label = None else: raise NotImplementedError() def resolve(self, f): if self.label: self.expr = f(self.label.name) def encode(self): return u32(self.expr) def __repr__(self): return 'DCD 0x{0:X}'.format(self.expr) @instruction class nop_ins(ArmInstruction): mnemonic = 'nop' operands = tuple() def encode(self): return bytes() def __repr__(self): return 'NOP' # Memory related class LS_imm5_base(ArmInstruction): """ ??? Rt, [Rn, imm5] """ operands = (Reg8Op, MemR8Rel) def __init__(self, rt, memop): assert memop.offset % 4 == 0 self.imm5 = memop.offset >> 2 self.rn = memop.basereg.num self.rt = rt self.memloc = memop assert self.rn < 8 assert self.rt.num < 8 def encode(self): Rn = self.rn Rt = self.rt.num imm5 = self.imm5 h = (self.opcode << 11) | (imm5 << 6) | (Rn << 3) | Rt return u16(h) def __repr__(self): return '{} {}, {}'.format(self.mnemonic, self.rt, self.memloc) @instruction class Str2(LS_imm5_base): mnemonic = 'STR' opcode = 0xC @classmethod def fromim(cls, im): mem = MemR8Rel(im.src[0], im.others[0]) return cls(im.src[1], mem) @instruction class Ldr2(LS_imm5_base): mnemonic = 'LDR' opcode = 0xD @classmethod def fromim(cls, im): mem = MemR8Rel(im.src[0], im.others[0]) return cls(im.dst[0], mem) class ls_sp_base_imm8(ArmInstruction): operands = (Reg8Op, MemSpRel) def __init__(self, rt, memop): self.rt = rt self.offset = memop.offset def encode(self): rt = self.rt.num assert rt < 8 imm8 = self.offset >> 2 assert imm8 < 256 h = (self.opcode << 8) | (rt << 8) | imm8 return u16(h) def __repr__(self): return '{} {}, [sp,#{}]'.format(self.mnemonic, self.rt, self.offset) def align(x, m): while ((x % m) != 0): x = x + 1 return x @instruction class Ldr3(ArmInstruction): """ ldr Rt, LABEL, load value from pc relative position """ mnemonic = 'ldr' operands = (Reg8Op, LabelRef) def __init__(self, rt, label): assert isinstance(label, LabelRef) self.rt = rt self.label = label self.offset = 0 @classmethod def fromim(cls, im): return cls(im.dst[0], im.others[0]) def resolve(self, f): la = f(self.label.name) sa = align(self.address + 2, 4) self.offset = (la - sa) if self.offset < 0: self.offset = 0 def encode(self): rt = self.rt.num assert rt < 8 assert self.offset % 4 == 0 imm8 = self.offset >> 2 assert imm8 < 256 assert imm8 >= 0 h = (0x9 << 11) | (rt << 8) | imm8 return u16(h) def __repr__(self): return 'LDR {}, {}'.format(self.rt, self.label.name) @instruction class Ldr1(ls_sp_base_imm8): """ ldr Rt, [SP, imm8] """ mnemonic = 'LDR' opcode = 0x98 @instruction class Str1(ls_sp_base_imm8): """ str Rt, [SP, imm8] """ mnemonic = 'STR' opcode = 0x90 @instruction class Mov3(ArmInstruction): """ mov Rd, imm8, move immediate value into register """ mnemonic = 'mov' opcode = 4 # 00100 Rd(3) imm8 operands = (Reg8Op, Imm8) def __init__(self, rd, imm): if type(imm) is int: imm = Imm8(imm) assert type(imm) is Imm8 self.imm = imm.imm assert type(rd) is Reg8Op, str(type(rd)) self.rd = rd @classmethod def fromim(cls, im): return cls(im.dst[0], im.others[0]) def encode(self): rd = self.rd.num opcode = self.opcode imm8 = self.imm h = (opcode << 11) | (rd << 8) | imm8 return u16(h) def __repr__(self): return 'MOV {}, {}'.format(self.rd, self.imm) # Arithmatics: class regregimm3_base(ArmInstruction): operands = (Reg8Op, Reg8Op, Imm3) def __init__(self, rd, rn, imm3): self.rd = rd self.rn = rn assert type(imm3) is Imm3 self.imm3 = imm3 @classmethod def fromim(cls, im): return cls(im.dst[0], im.src[0], im.others[0]) def encode(self): rd = self.rd.num rn = self.rn.num imm3 = self.imm3.imm opcode = self.opcode h = (self.opcode << 9) | (imm3 << 6) | (rn << 3) | rd return u16(h) def __repr__(self): return '{} {}, {}, {}'.format(self.mnemonic, self.rd, self.rn, self.imm3.imm) @instruction class Add2(regregimm3_base): """ add Rd, Rn, imm3 """ mnemonic = 'add' opcode = 0b0001110 @instruction class Sub2(regregimm3_base): """ sub Rd, Rn, imm3 """ mnemonic = 'sub' opcode = 0b0001111 class regregreg_base(ArmInstruction): """ ??? Rd, Rn, Rm """ operands = (Reg8Op, Reg8Op, Reg8Op) def __init__(self, rd, rn, rm): self.rd = rd self.rn = rn self.rm = rm @classmethod def fromim(cls, im): return cls(im.dst[0], im.src[0], im.src[1]) def encode(self): rd = self.rd.num rn = self.rn.num rm = self.rm.num h = (self.opcode << 9) | (rm << 6) | (rn << 3) | rd return u16(h) def __repr__(self): return '{} {}, {}, {}'.format(self.mnemonic, self.rd, self.rn, self.rm) @instruction class Add(regregreg_base): mnemonic = 'ADD' opcode = 0b0001100 @instruction class Sub(regregreg_base): mnemonic = 'SUB' opcode = 0b0001101 @instruction class Mov2(ArmInstruction): """ mov rd, rm """ operands = (ArmRegister, ArmRegister) mnemonic = 'MOV' def __init__(self, rd, rm): self.rd = rd self.rm = rm @classmethod def fromim(cls, im): return cls(im.dst[0], im.src[0]) def encode(self): Rd = self.rd.num & 0x7 D = (self.rd.num >> 3) & 0x1 Rm = self.rm.num opcode = 0b01000110 return u16((opcode << 8) | (D << 7) |(Rm << 3) | Rd) def __repr__(self): return '{} {}, {}'.format(self.mnemonic, self.rd, self.rm) @instruction class Mul(ArmInstruction): """ mul Rn, Rdm """ operands = (Reg8Op, Reg8Op) mnemonic = 'MUL' def __init__(self, rn, rdm): self.rn = rn self.rdm = rdm @classmethod def fromim(cls, im): assert im.src[1] is im.dst[0] return cls(im.src[0], im.dst[0]) def encode(self): rn = self.rn.num rdm = self.rdm.num opcode = 0b0100001101 h = (opcode << 6) | (rn << 3) | rdm return u16(h) def __repr__(self): return '{} {}, {}'.format(self.mnemonic, self.rn, self.rdm) class regreg_base(ArmInstruction): """ ??? Rdn, Rm """ operands = (Reg8Op, Reg8Op) # TODO: integrate with the code gen interface: src = (0, 1) dst = (0,) def __init__(self, rdn, rm): self.rdn = rdn self.rm = rm @classmethod def fromim(cls, im): return cls(im.src[0], im.src[1]) def encode(self): rdn = self.rdn.num rm = self.rm.num h = (self.opcode << 6) | (rm << 3) | rdn return u16(h) def __repr__(self): return '{} {}, {}'.format(self.mnemonic, self.rdn, self.rm) @instruction class movregreg_ins(regreg_base): """ mov Rd, Rm (reg8 operands) """ mnemonic = 'mov' opcode = 0 @instruction class And(regreg_base): mnemonic = 'AND' opcode = 0b0100000000 @instruction class Orr(regreg_base): mnemonic = 'ORR' opcode = 0b0100001100 @instruction class Cmp(regreg_base): mnemonic = 'CMP' opcode = 0b0100001010 @instruction class Lsl(regreg_base): mnemonic = 'LSL' opcode = 0b0100000010 @instruction class cmpregimm8_ins(ArmInstruction): """ cmp Rn, imm8 """ mnemonic = 'cmp' opcode = 5 # 00101 operands = (Reg8Op, Imm8) def __init__(self, rn, imm): self.rn = rn self.imm = imm def encode(self): rn = self.rn.num imm = self.imm.imm opcode = self.opcode h = (opcode << 11) | (rn << 8) | imm return u16(h) # Jumping: def wrap_negative(x, bits): b = struct.unpack('<I', struct.pack('<i', x))[0] mask = (1 << bits) - 1 return b & mask class jumpBase_ins(ArmInstruction): operands = (LabelRef,) def __init__(self, target_label): assert type(target_label) is LabelRef self.target = target_label self.offset = 0 def resolve(self, f): la = f(self.target.name) sa = self.address + 4 self.offset = (la - sa) def __repr__(self): return '{} {}'.format(self.mnemonic, self.target.name) @instruction class B(jumpBase_ins): mnemonic = 'B' def encode(self): imm11 = wrap_negative(self.offset >> 1, 11) h = (0b11100 << 11) | imm11 # | 1 # 1 to enable thumb mode return u16(h) @instruction class Bl(jumpBase_ins): mnemonic = 'BL' def encode(self): imm32 = wrap_negative(self.offset >> 1, 32) imm11 = imm32 & 0x7FF imm10 = (imm32 >> 11) & 0x3FF j1 = 1 # TODO: what do these mean? j2 = 1 s = (imm32 >> 24) & 0x1 h1 = (0b11110 << 11) | (s << 10) | imm10 h2 = (0b1101 << 12) | (j1 << 13) | (j2 << 11) | imm11 return u16(h1) + u16(h2) class cond_base_ins(jumpBase_ins): def encode(self): imm8 = wrap_negative(self.offset >> 1, 8) h = (0b1101 << 12) | (self.cond << 8) | imm8 return u16(h) @instruction class Beq(cond_base_ins): mnemonic = 'beq' cond = 0 @instruction class Bne(cond_base_ins): mnemonic = 'bne' cond = 1 @instruction class Blt(cond_base_ins): mnemonic = 'blt' cond = 0b1011 @instruction class Bgt(cond_base_ins): mnemonic = 'bgt' cond = 0b1100 @instruction class Push(ArmInstruction): operands = (RegisterSet,) mnemonic = 'push' def __init__(self, regs): if type(regs) is set: regs = RegisterSet(regs) assert (type(regs),) == self.operands, (type(regs),) self.regs = regs def __repr__(self): return '{0} {{{1}}}'.format(self.mnemonic, self.regs) def encode(self): reg_list = 0 M = 0 for n in self.regs.registerNumbers(): if n < 8: reg_list |= (1 << n) elif n == 14: M = 1 else: raise NotImplementedError('not implemented for this register') h = (0x5a << 9) | (M << 8) | reg_list return u16(h) @instruction class Pop(ArmInstruction): operands = (RegisterSet,) mnemonic = 'pop' def __init__(self, regs): if type(regs) is set: regs = RegisterSet(regs) assert (type(regs),) == self.operands, (type(regs),) self.regs = regs def __repr__(self): return '{0} {{{1}}}'.format(self.mnemonic, self.regs) def encode(self): reg_list = 0 P = 0 for n in self.regs.registerNumbers(): if n < 8: reg_list |= (1 << n) elif n == 15: P = 1 else: raise NotImplementedError('not implemented for this register') h = (0x5E << 9) | (P << 8) | reg_list return u16(h) @instruction class Yield(ArmInstruction): operands = () mnemonic = 'yield' def encode(self): return u16(0xbf10) # misc: # add/sub SP: class addspsp_base(ArmInstruction): operands = (RegSpOp, RegSpOp, Imm7) def __init__(self, _sp, _sp2, imm7): self.imm7 = imm7.imm assert self.imm7 % 4 == 0 self.imm7 >>= 2 def encode(self): return u16((self.opcode << 7) |self.imm7) def __repr__(self): return '{} sp, sp, {}'.format(self.mnemonic, self.imm7 << 2) @instruction class AddSp(addspsp_base): mnemonic = 'add' opcode = 0b101100000 @instruction class SubSp(addspsp_base): mnemonic = 'sub' opcode = 0b101100001