| blob | df4605bd8b1ac0687191060a9471d7f67f0869d0 |
1 #define SECSIZE (1 << 18)
2 #define MAXTMP (1 << 12)
4 /* basic types */
5 #define BT_SZMASK 0x00ff
6 #define BT_SIGNED 0x0100
7 #define BT_SZ(bt) ((bt) & BT_SZMASK)
9 #define O_SIGNED 0x100
10 /* binary instructions for o_bop() */
11 #define O_ADD 0x00
12 #define O_SUB 0x01
13 #define O_AND 0x02
14 #define O_OR 0x03
15 #define O_XOR 0x04
16 #define O_SHL 0x10
17 #define O_SHR 0x11
18 #define O_MUL 0x20
19 #define O_DIV 0x21
20 #define O_MOD 0x22
21 #define O_LT 0x30
22 #define O_GT 0x31
23 #define O_LE 0x32
24 #define O_GE 0x33
25 #define O_EQ 0x34
26 #define O_NEQ 0x35
27 /* unary instructions for o_uop() */
28 #define O_NEG 0x40
29 #define O_NOT 0x41
30 #define O_LNOT 0x42
32 /* operations */
44 /* pushing values */
51 /* handling locals */
55 /* branches */
60 /* conditional instructions */
64 /* data/bss sections */
68 /* functions */
71 /* output */
73 /* passes */
77 /*
78 * neatcc architecture-dependent code-generation interface
79 *
80 * To make maintaining three different architectures easier and unifying the
81 * optimization patch, I've extracted gen.c from x86.c and arm.c. The i_*()
82 * functions are now the low level architecture-specific code generation
83 * entry points. The differences between RISC and CISC architectures,
84 * actually the annoying asymmetry in CISC architecture, made this interface
85 * a bit more complex than it could have ideally been. Nevertheless, the
86 * benefits of extracting gen.c and the cleaner design, specially with the
87 * presence of the optimization patch, is worth the added complexity.
88 *
89 * I tried to make the interface as small as possible. I'll describe the
90 * key functions and macros here. Overall, there were many challenges for
91 * extracting gen.c including:
92 * + Different register sets; caller/callee saved and argument registers
93 * + CISC-style instructions that work on limited registers and parameters
94 * + Different instruction formats and immediate value limitations
95 * + Producing epilog, prolog, and local variable addresses when optimizing
96 *
97 * Instructions:
98 * + i_reg(): The mask of allowed registers for each operand of an instruction.
99 * If md is zero, we assume the destination register should be equal to the
100 * first register, as in CISC architectures. m2 can be zero which means
101 * the instruction doesn't have three operands. mt denotes the mask of
102 * registers that may lose their contents after the instruction.
103 * + i_load(), i_save(), i_mov(), i_num(), i_sym(): The name is clear.
104 * + i_imm(): Specifies if the given immediate can be encoded for the given
105 * instruction.
106 * + i_jmp(), i_fill(): Branching instructions. If rn >= 0, the branch is
107 * a conditional branch: jump only the register rn is zero (or nonzero if
108 * jc is nonzero). nbytes specifies the number of bytes necessary for
109 * holding the jump distance; useful if the architecture supports short
110 * branching instructions. i_fill() actually fills the jump at src in
111 * code segment. It returns the amount of bytes jumped.
112 * + i_args(): The offset of the first argument from the frame pointer.
113 * It is probably positive.
114 * + i_args(): The offset of the first local from the frame pointer.
115 * It is probably negative
116 * + tmpregs: Register that can be used for holding temporaries.
117 * + argregs: Register for holding the first N_ARGS arguments.
118 *
119 * There are a few other macros defined in arch headers. See x64.h as
120 * an example.
121 *
122 */
123 #ifdef NEATCC_ARM
125 #endif
126 #ifdef NEATCC_X64
128 #endif
129 #ifdef NEATCC_X86
131 #endif
133 /* intermediate instructions */
170 /* code segment text */