circuitpython/py/asmthumb.c
Damien George 8721087661 py: Big improvements to inline assembler.
Improved the Thumb assembler back end.  Added many more Thumb
instructions to the inline assembler.  Improved parsing of assembler
instructions and arguments.  Assembler functions can now be passed the
address of any object that supports the buffer protocol (to get the
address of the buffer).  Added an example of how to sum numbers from
an array in assembler.
2014-04-13 00:30:32 +01:00

446 lines
15 KiB
C

#include <stdio.h>
#include <assert.h>
#include <string.h>
#include "misc.h"
#include "mpconfig.h"
#include "asmthumb.h"
// wrapper around everything in this file
#if MICROPY_EMIT_THUMB || MICROPY_EMIT_INLINE_THUMB
#define UNSIGNED_FIT8(x) (((x) & 0xffffff00) == 0)
#define UNSIGNED_FIT16(x) (((x) & 0xffff0000) == 0)
#define SIGNED_FIT8(x) (((x) & 0xffffff80) == 0) || (((x) & 0xffffff80) == 0xffffff80)
#define SIGNED_FIT9(x) (((x) & 0xffffff00) == 0) || (((x) & 0xffffff00) == 0xffffff00)
#define SIGNED_FIT12(x) (((x) & 0xfffff800) == 0) || (((x) & 0xfffff800) == 0xfffff800)
struct _asm_thumb_t {
int pass;
uint code_offset;
uint code_size;
byte *code_base;
byte dummy_data[8];
uint max_num_labels;
int *label_offsets;
int num_locals;
uint push_reglist;
uint stack_adjust;
};
asm_thumb_t *asm_thumb_new(uint max_num_labels) {
asm_thumb_t *as;
as = m_new(asm_thumb_t, 1);
as->pass = 0;
as->code_offset = 0;
as->code_size = 0;
as->code_base = NULL;
as->max_num_labels = max_num_labels;
as->label_offsets = m_new(int, max_num_labels);
as->num_locals = 0;
return as;
}
void asm_thumb_free(asm_thumb_t *as, bool free_code) {
if (free_code) {
m_del(byte, as->code_base, as->code_size);
}
/*
if (as->label != NULL) {
int i;
for (i = 0; i < as->label->len; ++i)
{
Label *lab = &g_array_index(as->label, Label, i);
if (lab->unresolved != NULL)
g_array_free(lab->unresolved, true);
}
g_array_free(as->label, true);
}
*/
m_del_obj(asm_thumb_t, as);
}
void asm_thumb_start_pass(asm_thumb_t *as, int pass) {
as->pass = pass;
as->code_offset = 0;
if (pass == ASM_THUMB_PASS_2) {
memset(as->label_offsets, -1, as->max_num_labels * sizeof(int));
}
}
void asm_thumb_end_pass(asm_thumb_t *as) {
if (as->pass == ASM_THUMB_PASS_2) {
// calculate size of code in bytes
as->code_size = as->code_offset;
as->code_base = m_new(byte, as->code_size);
//printf("code_size: %u\n", as->code_size);
}
/*
// check labels are resolved
if (as->label != NULL)
{
int i;
for (i = 0; i < as->label->len; ++i)
if (g_array_index(as->label, Label, i).unresolved != NULL)
return false;
}
*/
}
// all functions must go through this one to emit bytes
STATIC byte *asm_thumb_get_cur_to_write_bytes(asm_thumb_t *as, int num_bytes_to_write) {
//printf("emit %d\n", num_bytes_to_write);
if (as->pass < ASM_THUMB_PASS_3) {
as->code_offset += num_bytes_to_write;
return as->dummy_data;
} else {
assert(as->code_offset + num_bytes_to_write <= as->code_size);
byte *c = as->code_base + as->code_offset;
as->code_offset += num_bytes_to_write;
return c;
}
}
uint asm_thumb_get_code_size(asm_thumb_t *as) {
return as->code_size;
}
void *asm_thumb_get_code(asm_thumb_t *as) {
// need to set low bit to indicate that it's thumb code
return (void *)(((machine_uint_t)as->code_base) | 1);
}
/*
STATIC void asm_thumb_write_byte_1(asm_thumb_t *as, byte b1) {
byte *c = asm_thumb_get_cur_to_write_bytes(as, 1);
c[0] = b1;
}
*/
STATIC void asm_thumb_write_op16(asm_thumb_t *as, uint op) {
byte *c = asm_thumb_get_cur_to_write_bytes(as, 2);
// little endian
c[0] = op;
c[1] = op >> 8;
}
STATIC void asm_thumb_write_op32(asm_thumb_t *as, uint op1, uint op2) {
byte *c = asm_thumb_get_cur_to_write_bytes(as, 4);
// little endian, op1 then op2
c[0] = op1;
c[1] = op1 >> 8;
c[2] = op2;
c[3] = op2 >> 8;
}
/*
#define IMM32_L0(x) ((x) & 0xff)
#define IMM32_L1(x) (((x) >> 8) & 0xff)
#define IMM32_L2(x) (((x) >> 16) & 0xff)
#define IMM32_L3(x) (((x) >> 24) & 0xff)
STATIC void asm_thumb_write_word32(asm_thumb_t *as, int w32) {
byte *c = asm_thumb_get_cur_to_write_bytes(as, 4);
c[0] = IMM32_L0(w32);
c[1] = IMM32_L1(w32);
c[2] = IMM32_L2(w32);
c[3] = IMM32_L3(w32);
}
*/
// rlolist is a bit map indicating desired lo-registers
#define OP_PUSH_RLIST(rlolist) (0xb400 | (rlolist))
#define OP_PUSH_RLIST_LR(rlolist) (0xb400 | 0x0100 | (rlolist))
#define OP_POP_RLIST(rlolist) (0xbc00 | (rlolist))
#define OP_POP_RLIST_PC(rlolist) (0xbc00 | 0x0100 | (rlolist))
#define OP_ADD_SP(num_words) (0xb000 | (num_words))
#define OP_SUB_SP(num_words) (0xb080 | (num_words))
void asm_thumb_entry(asm_thumb_t *as, int num_locals) {
// work out what to push and how many extra space to reserve on stack
// so that we have enough for all locals and it's aligned an 8-byte boundary
uint reglist;
uint stack_adjust;
if (num_locals < 0) {
num_locals = 0;
}
// don't ppop r0 because it's used for return value
switch (num_locals) {
case 0:
reglist = 0xf2;
stack_adjust = 0;
break;
case 1:
reglist = 0xf2;
stack_adjust = 0;
break;
case 2:
reglist = 0xfe;
stack_adjust = 0;
break;
case 3:
reglist = 0xfe;
stack_adjust = 0;
break;
default:
reglist = 0xfe;
stack_adjust = ((num_locals - 3) + 1) & (~1);
break;
}
asm_thumb_write_op16(as, OP_PUSH_RLIST_LR(reglist));
if (stack_adjust > 0) {
asm_thumb_write_op16(as, OP_SUB_SP(stack_adjust));
}
as->push_reglist = reglist;
as->stack_adjust = stack_adjust;
as->num_locals = num_locals;
}
void asm_thumb_exit(asm_thumb_t *as) {
if (as->stack_adjust > 0) {
asm_thumb_write_op16(as, OP_ADD_SP(as->stack_adjust));
}
asm_thumb_write_op16(as, OP_POP_RLIST_PC(as->push_reglist));
}
void asm_thumb_label_assign(asm_thumb_t *as, uint label) {
assert(label < as->max_num_labels);
if (as->pass == ASM_THUMB_PASS_2) {
// assign label offset
assert(as->label_offsets[label] == -1);
as->label_offsets[label] = as->code_offset;
} else if (as->pass == ASM_THUMB_PASS_3) {
// ensure label offset has not changed from PASS_2 to PASS_3
//printf("l%d: (at %d=%ld)\n", label, as->label_offsets[label], as->code_offset);
assert(as->label_offsets[label] == as->code_offset);
}
}
STATIC int get_label_dest(asm_thumb_t *as, uint label) {
assert(label < as->max_num_labels);
return as->label_offsets[label];
}
#define OP_FORMAT_2(op, rlo_dest, rlo_src, src_b) ((op) | ((src_b) << 6) | ((rlo_src) << 3) | (rlo_dest))
void asm_thumb_format_2(asm_thumb_t *as, uint op, uint rlo_dest, uint rlo_src, int src_b) {
assert(rlo_dest < REG_R8);
assert(rlo_src < REG_R8);
asm_thumb_write_op16(as, OP_FORMAT_2(op, rlo_dest, rlo_src, src_b));
}
#define OP_FORMAT_3(op, rlo, i8) ((op) | ((rlo) << 8) | (i8))
void asm_thumb_format_3(asm_thumb_t *as, uint op, uint rlo, int i8) {
assert(rlo < REG_R8);
asm_thumb_write_op16(as, OP_FORMAT_3(op, rlo, i8));
}
#define OP_FORMAT_4(op, rlo_dest, rlo_src) ((op) | ((rlo_src) << 3) | (rlo_dest))
void asm_thumb_format_4(asm_thumb_t *as, uint op, uint rlo_dest, uint rlo_src) {
assert(rlo_dest < REG_R8);
assert(rlo_src < REG_R8);
asm_thumb_write_op16(as, OP_FORMAT_4(op, rlo_dest, rlo_src));
}
#define OP_FORMAT_9_10(op, rlo_dest, rlo_base, offset) ((op) | (((offset) << 6) & 0x07c0) | ((rlo_base) << 3) | (rlo_dest))
void asm_thumb_format_9_10(asm_thumb_t *as, uint op, uint rlo_dest, uint rlo_base, uint offset) {
asm_thumb_write_op16(as, OP_FORMAT_9_10(op, rlo_dest, rlo_base, offset));
}
void asm_thumb_mov_reg_reg(asm_thumb_t *as, uint reg_dest, uint reg_src) {
uint op_lo;
if (reg_src < 8) {
op_lo = reg_src << 3;
} else {
op_lo = 0x40 | ((reg_src - 8) << 3);
}
if (reg_dest < 8) {
op_lo |= reg_dest;
} else {
op_lo |= 0x80 | (reg_dest - 8);
}
// mov reg_dest, reg_src
asm_thumb_write_op16(as, 0x4600 | op_lo);
}
#define OP_MOVW (0xf240)
#define OP_MOVT (0xf2c0)
// if loading lo half with movw, the i16 value will be zero extended into the r32 register!
STATIC void asm_thumb_mov_reg_i16(asm_thumb_t *as, uint mov_op, uint reg_dest, int i16_src) {
assert(reg_dest < REG_R15);
// mov[wt] reg_dest, #i16_src
asm_thumb_write_op32(as, mov_op | ((i16_src >> 1) & 0x0400) | ((i16_src >> 12) & 0xf), ((i16_src << 4) & 0x7000) | (reg_dest << 8) | (i16_src & 0xff));
}
// the i16_src value will be zero extended into the r32 register!
void asm_thumb_movw_reg_i16(asm_thumb_t *as, uint reg_dest, int i16_src) {
asm_thumb_mov_reg_i16(as, OP_MOVW, reg_dest, i16_src);
}
// the i16_src value will be zero extended into the r32 register!
void asm_thumb_movt_reg_i16(asm_thumb_t *as, uint reg_dest, int i16_src) {
asm_thumb_mov_reg_i16(as, OP_MOVT, reg_dest, i16_src);
}
void asm_thumb_ite_ge(asm_thumb_t *as) {
asm_thumb_write_op16(as, 0xbfac);
}
#define OP_B_N(byte_offset) (0xe000 | (((byte_offset) >> 1) & 0x07ff))
void asm_thumb_b_n(asm_thumb_t *as, uint label) {
int dest = get_label_dest(as, label);
int rel = dest - as->code_offset;
rel -= 4; // account for instruction prefetch, PC is 4 bytes ahead of this instruction
if (SIGNED_FIT12(rel)) {
asm_thumb_write_op16(as, OP_B_N(rel));
} else {
printf("asm_thumb_b_n: branch does not fit in 12 bits\n");
}
}
#define OP_BCC_N(cond, byte_offset) (0xd000 | ((cond) << 8) | (((byte_offset) >> 1) & 0x00ff))
void asm_thumb_bcc_n(asm_thumb_t *as, int cond, uint label) {
int dest = get_label_dest(as, label);
int rel = dest - as->code_offset;
rel -= 4; // account for instruction prefetch, PC is 4 bytes ahead of this instruction
if (SIGNED_FIT9(rel)) {
asm_thumb_write_op16(as, OP_BCC_N(cond, rel));
} else {
printf("asm_thumb_bcc_n: branch does not fit in 9 bits\n");
}
}
void asm_thumb_mov_reg_i32(asm_thumb_t *as, uint reg_dest, machine_uint_t i32) {
// movw, movt does it in 8 bytes
// ldr [pc, #], dw does it in 6 bytes, but we might not reach to end of code for dw
asm_thumb_mov_reg_i16(as, OP_MOVW, reg_dest, i32);
asm_thumb_mov_reg_i16(as, OP_MOVT, reg_dest, i32 >> 16);
}
void asm_thumb_mov_reg_i32_optimised(asm_thumb_t *as, uint reg_dest, int i32) {
if (reg_dest < 8 && UNSIGNED_FIT8(i32)) {
asm_thumb_mov_rlo_i8(as, reg_dest, i32);
} else if (UNSIGNED_FIT16(i32)) {
asm_thumb_mov_reg_i16(as, OP_MOVW, reg_dest, i32);
} else {
asm_thumb_mov_reg_i32(as, reg_dest, i32);
}
}
#define OP_STR_TO_SP_OFFSET(rlo_dest, word_offset) (0x9000 | ((rlo_dest) << 8) | ((word_offset) & 0x00ff))
#define OP_LDR_FROM_SP_OFFSET(rlo_dest, word_offset) (0x9800 | ((rlo_dest) << 8) | ((word_offset) & 0x00ff))
void asm_thumb_mov_local_reg(asm_thumb_t *as, int local_num, uint rlo_src) {
assert(rlo_src < REG_R8);
int word_offset = as->num_locals - local_num - 1;
assert(as->pass < ASM_THUMB_PASS_3 || word_offset >= 0);
asm_thumb_write_op16(as, OP_STR_TO_SP_OFFSET(rlo_src, word_offset));
}
void asm_thumb_mov_reg_local(asm_thumb_t *as, uint rlo_dest, int local_num) {
assert(rlo_dest < REG_R8);
int word_offset = as->num_locals - local_num - 1;
assert(as->pass < ASM_THUMB_PASS_3 || word_offset >= 0);
asm_thumb_write_op16(as, OP_LDR_FROM_SP_OFFSET(rlo_dest, word_offset));
}
#define OP_ADD_REG_SP_OFFSET(rlo_dest, word_offset) (0xa800 | ((rlo_dest) << 8) | ((word_offset) & 0x00ff))
void asm_thumb_mov_reg_local_addr(asm_thumb_t *as, uint rlo_dest, int local_num) {
assert(rlo_dest < REG_R8);
int word_offset = as->num_locals - local_num - 1;
assert(as->pass < ASM_THUMB_PASS_3 || word_offset >= 0);
asm_thumb_write_op16(as, OP_ADD_REG_SP_OFFSET(rlo_dest, word_offset));
}
// this could be wrong, because it should have a range of +/- 16MiB...
#define OP_BW_HI(byte_offset) (0xf000 | (((byte_offset) >> 12) & 0x07ff))
#define OP_BW_LO(byte_offset) (0xb800 | (((byte_offset) >> 1) & 0x07ff))
void asm_thumb_b_label(asm_thumb_t *as, uint label) {
int dest = get_label_dest(as, label);
int rel = dest - as->code_offset;
rel -= 4; // account for instruction prefetch, PC is 4 bytes ahead of this instruction
if (dest >= 0 && rel <= -4) {
// is a backwards jump, so we know the size of the jump on the first pass
// calculate rel assuming 12 bit relative jump
if (SIGNED_FIT12(rel)) {
asm_thumb_write_op16(as, OP_B_N(rel));
} else {
goto large_jump;
}
} else {
// is a forwards jump, so need to assume it's large
large_jump:
asm_thumb_write_op32(as, OP_BW_HI(rel), OP_BW_LO(rel));
}
}
// all these bit arithmetics need coverage testing!
#define OP_BCC_W_HI(cond, byte_offset) (0xf000 | ((cond) << 6) | (((byte_offset) >> 10) & 0x0400) | (((byte_offset) >> 14) & 0x003f))
#define OP_BCC_W_LO(byte_offset) (0x8000 | ((byte_offset) & 0x2000) | (((byte_offset) >> 1) & 0x0fff))
void asm_thumb_bcc_label(asm_thumb_t *as, int cond, uint label) {
int dest = get_label_dest(as, label);
int rel = dest - as->code_offset;
rel -= 4; // account for instruction prefetch, PC is 4 bytes ahead of this instruction
if (dest >= 0 && rel <= -4) {
// is a backwards jump, so we know the size of the jump on the first pass
// calculate rel assuming 9 bit relative jump
if (SIGNED_FIT9(rel)) {
asm_thumb_write_op16(as, OP_BCC_N(cond, rel));
} else {
goto large_jump;
}
} else {
// is a forwards jump, so need to assume it's large
large_jump:
asm_thumb_write_op32(as, OP_BCC_W_HI(cond, rel), OP_BCC_W_LO(rel));
}
}
#define OP_BLX(reg) (0x4780 | ((reg) << 3))
#define OP_SVC(arg) (0xdf00 | (arg))
void asm_thumb_bl_ind(asm_thumb_t *as, void *fun_ptr, uint fun_id, uint reg_temp) {
/* TODO make this use less bytes
uint rlo_base = REG_R3;
uint rlo_dest = REG_R7;
uint word_offset = 4;
asm_thumb_write_op16(as, 0x0000);
asm_thumb_write_op16(as, 0x6800 | (word_offset << 6) | (rlo_base << 3) | rlo_dest); // ldr rlo_dest, [rlo_base, #offset]
asm_thumb_write_op16(as, 0x4780 | (REG_R9 << 3)); // blx reg
*/
if (0) {
// load ptr to function into register using immediate, then branch
// not relocatable
asm_thumb_mov_reg_i32(as, reg_temp, (machine_uint_t)fun_ptr);
asm_thumb_write_op16(as, OP_BLX(reg_temp));
} else if (1) {
asm_thumb_write_op16(as, OP_FORMAT_9_10(ASM_THUMB_FORMAT_9_LDR | ASM_THUMB_FORMAT_9_WORD_TRANSFER, reg_temp, REG_R7, fun_id));
asm_thumb_write_op16(as, OP_BLX(reg_temp));
} else {
// use SVC
asm_thumb_write_op16(as, OP_SVC(fun_id));
}
}
#endif // MICROPY_EMIT_THUMB || MICROPY_EMIT_INLINE_THUMB