//
// RMAC - Reboot's Macro Assembler for the Atari Jaguar Console System
// MACH.C - Code Generation
-// Copyright (C) 199x Landon Dyer, 2011 Reboot and Friends
+// Copyright (C) 199x Landon Dyer, 2017 Reboot and Friends
// RMAC derived from MADMAC v1.07 Written by Landon Dyer, 1986
-// Source Utilised with the Kind Permission of Landon Dyer
+// Source utilised with the kind permission of Landon Dyer
//
#include "mach.h"
#include "direct.h"
#include "token.h"
#include "procln.h"
-#include "risca.h"
+#include "riscasm.h"
+#include "rmac.h"
#define DEF_KW
#include "kwtab.h"
+
+// Fucntion prototypes
+int m_unimp(WORD, WORD), m_badmode(WORD, WORD), m_bad6mode(WORD, WORD), m_bad6inst(WORD, WORD);
+int m_self(WORD, WORD);
+int m_abcd(WORD, WORD);
+int m_reg(WORD, WORD);
+int m_imm(WORD, WORD);
+int m_imm8(WORD, WORD);
+int m_shi(WORD, WORD);
+int m_shr(WORD, WORD);
+int m_bitop(WORD, WORD);
+int m_exg(WORD, WORD);
+int m_ea(WORD, WORD);
+int m_br(WORD, WORD);
+int m_dbra(WORD, WORD);
+int m_link(WORD, WORD);
+int m_adda(WORD, WORD);
+int m_addq(WORD, WORD);
+//int m_move(WORD, int);
+int m_move(WORD, WORD);
+int m_moveq(WORD, WORD);
+int m_usp(WORD, WORD);
+int m_movep(WORD, WORD);
+int m_trap(WORD, WORD);
+int m_movem(WORD, WORD);
+int m_clra(WORD, WORD);
+
// Common error messages
-char * range_error = "expression out of range";
-char * abs_error = "illegal absolute expression";
-char * seg_error = "bad (section) expression";
-char * rel_error = "illegal relative address";
-char * siz_error = "bad size specified";
-char * undef_error = "undefined expression";
-char * fwd_error = "forward or undefined expression";
+char range_error[] = "expression out of range";
+char abs_error[] = "illegal absolute expression";
+char seg_error[] = "bad (section) expression";
+char rel_error[] = "illegal relative address";
+char siz_error[] = "bad size specified";
+char undef_error[] = "undefined expression";
+char fwd_error[] = "forward or undefined expression";
extern int ea0gen(WORD);
extern int ea1gen(WORD);
// Include code tables
MNTAB machtab[] = {
- { (WORD)-1, (unsigned long)-1L, (unsigned long)-1L, 0x0000, 0, m_badmode }, // 0
+// { (WORD)-1, (unsigned long)-1L, (unsigned long)-1L, 0x0000, 0, m_badmode }, // 0
+ { 0xFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0x0000, 0, m_badmode }, // 0
#include "68ktab.h"
- { 0, 0L, 0L, 0x0000, 0, m_unimp } // Last entry
+ { 0, 0L, 0L, 0x0000, 0, m_unimp } // Last entry
};
// Register number << 9
WORD reg_9[8] = {
- 0, 1<<9, 2<<9, 3<<9,
- 4<<9, 5<<9, 6<<9, 7<<9
+ 0, 1 << 9, 2 << 9, 3 << 9, 4 << 9, 5 << 9, 6 << 9, 7 << 9
};
// SIZB==>00, SIZW==>01, SIZL==>10, SIZN==>01 << 6
WORD siz_6[] = {
- (WORD)-1, // n/a
- 0, // SIZB
- 1<<6, (WORD)-1, // SIZW, n/a
- 2<<6, (WORD)-1, (WORD)-1, (WORD)-1, // SIZL, n/a, n/a, n/a
- 1<<6 // SIZN
+ (WORD)-1, // n/a
+ 0, // SIZB
+ 1<<6, (WORD)-1, // SIZW, n/a
+ 2<<6, (WORD)-1, (WORD)-1, (WORD)-1, // SIZL, n/a, n/a, n/a
+ 1<<6 // SIZN
};
// Byte/word/long size for MOVE instrs
WORD siz_12[] = {
(WORD)-1,
- 0x1000, // Byte
- 0x3000, (WORD)-1, // Word
- 0x2000, (WORD)-1, (WORD)-1, (WORD)-1, // Long
- 0x3000 // Word (SIZN)
+ 0x1000, // Byte
+ 0x3000, (WORD)-1, // Word
+ 0x2000, (WORD)-1, (WORD)-1, (WORD)-1, // Long
+ 0x3000 // Word (SIZN)
};
// Word/long size (0=.w, 1=.l) in bit 8
WORD lwsiz_8[] = {
- (WORD)-1, // n/a
- (WORD)-1, // SIZB
- 0, (WORD)-1, // SIZW, n/a
- 1<<8, (WORD)-1, (WORD)-1, (WORD)-1, // SIZL, n/a, n/a, n/a
- 0 // SIZN
+ (WORD)-1, // n/a
+ (WORD)-1, // SIZB
+ 0, (WORD)-1, // SIZW, n/a
+ 1<<8, (WORD)-1, (WORD)-1, (WORD)-1, // SIZL, n/a, n/a, n/a
+ 0 // SIZN
};
// Addressing mode in bits 6..11 (register/mode fields are reversed)
// Error messages
-int m_unimp(void)
+int m_unimp(WORD unused1, WORD unused2)
{
return (int)error("unimplemented mnemonic");
}
-int m_badmode(void)
+//int m_badmode(void)
+int m_badmode(WORD unused1, WORD unused2)
{
return (int)error("inappropriate addressing mode");
}
-int m_self(WORD inst)
+int m_self(WORD inst, WORD usused)
{
D_word(inst);
return 0;
//
// Do one EA in bits 0..5
-//
+//
// Bits in `inst' have the following meaning:
-//
+//
// Bit zero specifies which ea (ea0 or ea1) to generate in the lower six bits
// of the instr.
-//
+//
// If bit one is set, the OTHER ea (the one that wasn't generated by bit zero)
// is generated after the instruction. Regardless of bit 0's value, ea0 is
// always deposited in memory before ea1.
-//
+//
// If bit two is set, standard size bits are set in the instr in bits 6 and 7.
-//
+//
// If bit four is set, bit three specifies which eaXreg to place in bits 9..11
// of the instr.
//
int m_ea(WORD inst, WORD siz)
{
- WORD flg;
-
- flg = inst; // Save flag bits
- inst &= ~0x3f; // Clobber flag bits in instr
+ WORD flg = inst; // Save flag bits
+ inst &= ~0x3F; // Clobber flag bits in instr
- if (flg & 4) // Install "standard" instr size bits
+ // Install "standard" instr size bits
+ if (flg & 4)
inst |= siz_6[siz];
if (flg & 16)
- { // OR-in register number
+ {
+ // OR-in register number
if (flg & 8)
- {
- inst |= reg_9[a1reg]; // ea1reg in bits 9..11
- }
+ inst |= reg_9[a1reg]; // ea1reg in bits 9..11
else
- {
- inst |= reg_9[a0reg]; // ea0reg in bits 9..11
- }
+ inst |= reg_9[a0reg]; // ea0reg in bits 9..11
}
if (flg & 1)
- { // Use am1
- inst |= am1 | a1reg; // Get ea1 into instr
- D_word(inst); // Deposit instr
+ {
+ // Use am1
+ inst |= am1 | a1reg; // Get ea1 into instr
+ D_word(inst); // Deposit instr
- if (flg & 2) // Generate ea0 if requested
+ // Generate ea0 if requested
+ if (flg & 2)
ea0gen(siz);
- ea1gen(siz); // Generate ea1
+ ea1gen(siz); // Generate ea1
}
else
- { // Use am0
- inst |= am0 | a0reg; // Get ea0 into instr
- D_word(inst); // Deposit instr
- ea0gen(siz); // Generate ea0
+ {
+ // Use am0
+ inst |= am0 | a0reg; // Get ea0 into instr
+ D_word(inst); // Deposit instr
+ ea0gen(siz); // Generate ea0
- if (flg & 2) // Generate ea1 if requested
+ // Generate ea1 if requested
+ if (flg & 2)
ea1gen(siz);
}
int m_abcd(WORD inst, WORD siz)
{
if (inst & 1)
- { // Install size bits
- --inst;
+ {
+ // Install size bits
+ inst--;
inst |= siz_6[siz];
}
{
inst |= am0 | a0reg | lwsiz_8[siz] | reg_9[a1reg];
D_word(inst);
- ea0gen(siz); // Gen EA
+ ea0gen(siz); // Generate EA
return 0;
}
//
// If bit 0 of `inst' is 1, install size bits in bits 6..7 of instr.
// If bit 1 of `inst' is 1, install a1reg in bits 9..11 of instr.
-//
+//
int m_reg(WORD inst, WORD siz)
{
- if (inst & 1) // Install size bits
+ if (inst & 1)
+ // Install size bits
inst |= siz_6[siz];
- if (inst & 2) // Install other register (9..11)
+ if (inst & 2)
+ // Install other register (9..11)
inst |= reg_9[a1reg];
- inst &= ~7; // Clear off crufty bits
- inst |= a0reg; // Install first register
+ inst &= ~7; // Clear off crufty bits
+ inst |= a0reg; // Install first register
D_word(inst);
return 0;
}
else
{
- fixup(FU_QUICK, sloc, a0expr);
+ AddFixup(FU_QUICK, sloc, a0expr);
D_word(inst);
}
{
// Enforce instruction sizes
if (am1 == DREG)
- { // X,Dn must be .n or .l
- if (siz & (SIZB|SIZW))
+ { // X,Dn must be .n or .l
+ if (siz & (SIZB | SIZW))
return error(siz_error);
}
- else if (siz & (SIZW|SIZL)) // X,ea must be .n or .b
+ else if (siz & (SIZW | SIZL)) // X,ea must be .n or .b
return error(siz_error);
// Construct instr and EAs
if (am0 == IMMED)
{
D_word(inst);
- ea0gen(SIZB); // Immediate bit number
+ ea0gen(SIZB); // Immediate bit number
}
else
{
D_word(inst);
}
- ea1gen(SIZB); // ea to bit-munch
+ // ea to bit-munch
+ ea1gen(SIZB);
return 0;
}
}
else
{
- fixup(FU_WORD|FU_PCREL|FU_ISBRA, sloc, a1expr);
+ AddFixup(FU_WORD | FU_PCREL | FU_ISBRA, sloc, a1expr);
D_word(0);
}
siz = siz;
if (am0 == DREG && am1 == DREG)
- m = 0x0040; // Dn,Dn
+ m = 0x0040; // Dn,Dn
else if (am0 == AREG && am1 == AREG)
- m = 0x0048; // An,An
+ m = 0x0048; // An,An
else
{
if (am0 == AREG)
- { // Dn,An or An,Dn
- m = a1reg; // Get AREG into a1reg
+ { // Dn,An or An,Dn
+ m = a1reg; // Get AREG into a1reg
a1reg = a0reg;
a0reg = m;
}
//
// Handle MOVE <C_ALL> <C_ALTDATA>
// MOVE <C_ALL> <M_AREG>
-//
+//
// Optimize MOVE.L #<smalldata>,D0 to a MOVEQ
//
-int m_move(WORD inst, int siz)
+int m_move(WORD inst, WORD size)
{
+ // Cast the passed in value to an int
+ int siz = (int)size;
+
// Try to optimize to MOVEQ
- if (siz == SIZL && am0 == IMMED && am1 == DREG
+ if (optim_flags[OPT_MOVEL_MOVEQ] && siz == SIZL && am0 == IMMED && am1 == DREG
&& (a0exattr & (TDB|DEFINED)) == DEFINED && a0exval + 0x80 < 0x100)
{
m_moveq((WORD)0x7000, (WORD)0);
+
+ if (sbra_flag)
+ warn("move.l #size,dx converted to moveq");
}
else
{
ea0gen((WORD)siz);
if (am1 >= ADISP)
- ea1gen((WORD)siz);
+ ea1gen((WORD)siz | 0x8000); // Tell ea1gen we're move ea,ea
}
return 0;
siz = siz;
if (am0 == AM_USP)
- inst |= a1reg; // USP,An
+ inst |= a1reg; // USP, An
else
- inst |= a0reg; // An,USP
+ inst |= a0reg; // An, USP
D_word(inst);
{
siz = siz;
+ // Arrange for future fixup
if (!(a0exattr & DEFINED))
- { // Arrange for future fixup
- fixup(FU_BYTE|FU_SEXT, sloc+1, a0expr);
- a0exval = 0;
+ {
+ AddFixup(FU_BYTE | FU_SEXT, sloc + 1, a0expr);
+ a0exval = 0;
}
else if (a0exval + 0x100 >= 0x200)
return error(range_error);
- inst |= reg_9[a1reg] | (a0exval & 0xff);
+ inst |= reg_9[a1reg] | (a0exval & 0xFF);
D_word(inst);
return 0;
//
-// movep Dn,disp(An) -- movep disp(An),Dn
+// movep Dn, disp(An) -- movep disp(An), Dn
//
int m_movep(WORD inst, WORD siz)
{
- //WORD k;
-
if (siz == SIZL)
inst |= 0x0040;
D_word(inst);
if (am1 == AIND)
- {
- D_word(0);
- }
- else
+ D_word(0)
+ else
ea1gen(siz);
}
else
D_word(inst);
if (am0 == AIND)
- {
- D_word(0);
- }
- else
+ D_word(0)
+ else
ea0gen(siz);
}
if (a0exattr & DEFINED)
{
if ((a0exattr & TDB) != cursect)
+//{
+//printf("m_br(): a0exattr = %X, cursect = %X, a0exval = %X, sloc = %X\n", a0exattr, cursect, a0exval, sloc);
return error(rel_error);
+//}
v = a0exval - (sloc + 2);
// Optimize branch instr. size
if (siz == SIZN)
{
- if (v != 0 && v + 0x80 < 0x100)
- { // Fits in .B
- inst |= v & 0xff;
+ if (optim_flags[OPT_BSR_BCC_S] && v != 0 && v + 0x80 < 0x100)
+ {
+ // Fits in .B
+ inst |= v & 0xFF;
D_word(inst);
+ if (sbra_flag)
+ warn("Bcc.w/BSR.w converted to .s");
return 0;
}
else
- { // Fits in .W
+ {
+ // Fits in .W
if (v + 0x8000 > 0x10000)
return error(range_error);
if (v + 0x80 >= 0x100)
return error(range_error);
- inst |= v & 0xff;
+ inst |= v & 0xFF;
D_word(inst);
}
else
siz = SIZW;
if (siz == SIZB)
- { // .B
- fixup(FU_BBRA|FU_PCREL|FU_SEXT, sloc, a0expr);
+ {
+ // .B
+ AddFixup(FU_BBRA | FU_PCREL | FU_SEXT, sloc, a0expr);
D_word(inst);
return 0;
}
else
- { // .W
+ {
+ // .W
D_word(inst);
- fixup(FU_WORD|FU_PCREL|FU_LBRA|FU_ISBRA, sloc, a0expr);
+ AddFixup(FU_WORD | FU_PCREL | FU_LBRA | FU_ISBRA, sloc, a0expr);
D_word(0);
}
if (a0exattr & DEFINED)
{
- if (a0exval > 8 || a0exval == 0) // Range in 1..8
+ if (a0exval > 8 || a0exval == 0) // Range in 1..8
return error(range_error);
inst |= (a0exval & 7) << 9;
}
else
{
- fixup(FU_QUICK, sloc, a0expr);
+ AddFixup(FU_QUICK, sloc, a0expr);
D_word(inst);
}
inst |= a0exval;
D_word(inst);
}
- else
+ else
return error(undef_error);
return 0;
inst |= 0x0040;
if (*tok == '#')
- { // Handle #<expr>,ea
- ++tok;
+ {
+ // Handle #<expr>, ea
+ tok++;
if (abs_expr(&eval) != OK)
return 0;
}
if (*tok >= KW_D0 && *tok <= KW_A7)
- { // <rlist>,ea
+ {
+ // <rlist>, ea
if (reglist(&rmask) < 0)
return 0;
inst |= am0 | a0reg;
- if (!(amsktab[am0] & (C_ALTCTRL|M_APREDEC)))
+ if (!(amsktab[am0] & (C_ALTCTRL | M_APREDEC)))
return error("invalid addressing mode");
// If APREDEC, reverse register mask
}
}
else
- { // ea,<rlist>
+ {
+ // ea, <rlist>
if (amode(0) < 0)
return 0;
return error("missing register list");
if (*tok == '#')
- { // ea,#<expr>
- ++tok;
+ {
+ // ea, #<expr>
+ tok++;
if (abs_expr(&eval) != OK)
return 0;
else if (reglist(&rmask) < 0)
return 0;
- if (!(amsktab[am0] & (C_CTRL|M_APOSTINC)))
+ if (!(amsktab[am0] & (C_CTRL | M_APOSTINC)))
return error("invalid addressing mode");
}
return 0;
}
+