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|
/*
* Copyright (C) 2006-2010 Michael Buesch <m@bues.ch>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2
* as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include "main.h"
#include "list.h"
#include "util.h"
#include "parser.h"
#include "args.h"
#include "initvals.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
extern int yyparse(void);
extern int yydebug;
struct file infile;
const char *infile_name;
const char *outfile_name;
struct out_operand {
enum {
OUTOPER_NORMAL,
OUTOPER_LABELREF,
} type;
union {
unsigned int operand; /* For NORMAL */
struct label *label; /* For LABELREF */
} u;
};
struct code_output {
enum {
OUT_INSN,
OUT_LABEL,
} type;
/* Set to true, if this is a jump instruction.
* This is only used when assembling RET to check
* whether the previous instruction was a jump or not. */
bool is_jump_insn;
unsigned int opcode;
struct out_operand operands[3];
/* The absolute address of this instruction.
* Only used in resolve_labels(). */
unsigned int address;
const char *labelname; /* only for OUT_LABEL */
/* Set to 1, if this is the %start instruction. */
int is_start_insn;
struct list_head list;
};
struct assembler_context {
/* The architecture version (802.11 core revision) */
unsigned int arch;
struct label *start_label;
/* Tracking stuff */
struct statement *cur_stmt;
struct list_head output;
};
#define for_each_statement(ctx, s) \
list_for_each_entry(s, &infile.sl, list) { \
ctx->cur_stmt = s;
#define for_each_statement_end(ctx, s) \
} do { ctx->cur_stmt = NULL; } while (0)
#define _msg_helper(type, stmt, msg, x...) do { \
fprintf(stderr, "Assembler " type); \
if (stmt) { \
fprintf(stderr, " (file \"%s\", line %u)", \
stmt->info.file, \
stmt->info.lineno); \
} \
fprintf(stderr, ":\n " msg "\n" ,##x); \
} while (0)
#define asm_error(ctx, msg, x...) do { \
_msg_helper("ERROR", (ctx)->cur_stmt, msg ,##x); \
exit(1); \
} while (0)
#define asm_warn(ctx, msg, x...) \
_msg_helper("warning", (ctx)->cur_stmt, msg ,##x)
#define asm_info(ctx, msg, x...) \
_msg_helper("info", (ctx)->cur_stmt, msg ,##x)
static void eval_directives(struct assembler_context *ctx)
{
struct statement *s;
struct asmdir *ad;
struct label *l;
int have_start_label = 0;
int have_arch = 0;
unsigned int arch_fallback = 0;
for_each_statement(ctx, s) {
if (s->type == STMT_ASMDIR) {
ad = s->u.asmdir;
switch (ad->type) {
case ADIR_ARCH:
if (have_arch)
asm_error(ctx, "Multiple %%arch definitions");
ctx->arch = ad->u.arch;
if (ctx->arch > 5 && ctx->arch < 15)
arch_fallback = 5;
if (ctx->arch > 15)
arch_fallback = 15;
if (arch_fallback) {
asm_warn(ctx, "Using %%arch %d is incorrect. "
"The wireless core revision %d uses the "
"firmware architecture %d. So use %%arch %d",
ctx->arch, ctx->arch, arch_fallback, arch_fallback);
ctx->arch = arch_fallback;
}
if (ctx->arch != 5 && ctx->arch != 15) {
asm_error(ctx, "Architecture version %u unsupported",
ctx->arch);
}
have_arch = 1;
break;
case ADIR_START:
if (have_start_label)
asm_error(ctx, "Multiple %%start definitions");
ctx->start_label = ad->u.start;
have_start_label = 1;
break;
default:
asm_error(ctx, "Unknown ASM directive");
}
}
} for_each_statement_end(ctx, s);
if (!have_arch)
asm_error(ctx, "No %%arch defined");
if (!have_start_label)
asm_info(ctx, "Using start address 0");
}
static bool is_possible_imm(unsigned int imm)
{
unsigned int mask;
/* Immediates are only possible up to 16bit (wordsize). */
mask = ~0;
mask <<= 16;
if (imm & (1 << 15)) {
if ((imm & mask) != mask &&
(imm & mask) != 0)
return 0;
} else {
if ((imm & mask) != 0)
return 0;
}
return 1;
}
static unsigned int immediate_nr_bits(struct assembler_context *ctx)
{
switch (ctx->arch) {
case 5:
return 10; /* 10 bits */
case 15:
return 11; /* 11 bits */
}
asm_error(ctx, "Internal error: immediate_nr_bits unknown arch\n");
}
static bool is_valid_imm(struct assembler_context *ctx,
unsigned int imm)
{
unsigned int mask;
unsigned int immediate_size;
/* This function checks if the immediate value is representable
* as a native immediate operand.
*
* For v5 architecture the immediate can be 10bit long.
* For v15 architecture the immediate can be 11bit long.
*
* The value is sign-extended, so we allow values
* of 0xFFFA, for example.
*/
if (!is_possible_imm(imm))
return 0;
imm &= 0xFFFF;
immediate_size = immediate_nr_bits(ctx);
/* First create a mask with all possible bits for
* an immediate value unset. */
mask = (~0 << immediate_size) & 0xFFFF;
/* Is the sign bit of the immediate set? */
if (imm & (1 << (immediate_size - 1))) {
/* Yes, so all bits above that must also
* be set, otherwise we can't represent this
* value in an operand. */
if ((imm & mask) != mask)
return 0;
} else {
/* All bits above the immediate's size must
* be unset. */
if (imm & mask)
return 0;
}
return 1;
}
/* This checks if the value is nonzero and a power of two. */
static bool is_power_of_two(unsigned int value)
{
return (value && ((value & (value - 1)) == 0));
}
/* This checks if all bits set in the mask are contiguous.
* Zero is also considered a contiguous mask. */
static bool is_contiguous_bitmask(unsigned int mask)
{
unsigned int low_zeros_mask;
bool is_contiguous;
if (mask == 0)
return 1;
/* Turn the lowest zeros of the mask into a bitmask.
* Example: 0b00011000 -> 0b00000111 */
low_zeros_mask = (mask - 1) & ~mask;
/* Adding the low_zeros_mask to the original mask
* basically is a bitwise OR operation.
* If the original mask was contiguous, we end up with a
* contiguous bitmask from bit 0 to the highest bit
* set in the original mask. Adding 1 will result in a single
* bit set, which is a power of two. */
is_contiguous = is_power_of_two(mask + low_zeros_mask + 1);
return is_contiguous;
}
static unsigned int generate_imm_operand(struct assembler_context *ctx,
const struct immediate *imm)
{
unsigned int val, tmp;
unsigned int mask;
val = 0xC00;
if (ctx->arch == 15)
val <<= 1;
tmp = imm->imm;
if (!is_valid_imm(ctx, tmp)) {
asm_warn(ctx, "IMMEDIATE 0x%X (%d) too long "
"(> %u bits + sign). Did you intend to "
"use implicit sign extension?",
tmp, (int)tmp, immediate_nr_bits(ctx) - 1);
}
if (ctx->arch == 15)
tmp &= 0x7FF;
else
tmp &= 0x3FF;
val |= tmp;
return val;
}
static unsigned int generate_reg_operand(struct assembler_context *ctx,
const struct registr *reg)
{
unsigned int val = 0;
switch (reg->type) {
case GPR:
val |= 0xBC0;
if (ctx->arch == 15)
val <<= 1;
if (reg->nr & ~0x3F) /* REVISIT: 128 regs for v15 arch possible? Probably not... */
asm_error(ctx, "GPR-nr too big");
val |= reg->nr;
break;
case SPR:
val |= 0x800;
if (ctx->arch == 15)
val <<= 1;
if (reg->nr & ~0x1FF)
asm_error(ctx, "SPR-nr too big");
val |= reg->nr;
break;
case OFFR:
val |= 0x860;
if (ctx->arch == 15)
val <<= 1;
if (reg->nr & ~0x7)
asm_error(ctx, "OFFR-nr too big");
val |= reg->nr;
break;
default:
asm_error(ctx, "generate_reg_operand() regtype");
}
return val;
}
static unsigned int generate_mem_operand(struct assembler_context *ctx,
const struct memory *mem)
{
unsigned int val = 0, off, reg, off_mask, reg_shift;
switch (mem->type) {
case MEM_DIRECT:
off = mem->offset;
switch (ctx->arch) {
case 5:
if (off & ~0x7FF) {
asm_warn(ctx, "DIRECT memoffset 0x%X too long (> 11 bits)", off);
off &= 0x7FF;
}
break;
case 15:
if (off & ~0xFFF) {
asm_warn(ctx, "DIRECT memoffset 0x%X too long (> 12 bits)", off);
off &= 0xFFF;
}
break;
default:
asm_error(ctx, "Internal error: generate_mem_operand invalid arch");
}
val |= off;
break;
case MEM_INDIRECT:
switch (ctx->arch) {
case 5:
val = 0xA00;
off_mask = 0x3F;
reg_shift = 6;
break;
case 15:
val = 0x1400;
off_mask = 0x7F;
reg_shift = 7;
break;
default:
asm_error(ctx, "Internal error: MEM_INDIRECT invalid arch\n");
}
off = mem->offset;
reg = mem->offr_nr;
if (off & ~off_mask) {
asm_warn(ctx, "INDIRECT memoffset 0x%X too long (> %u bits)",
off, reg_shift);
off &= off_mask;
}
if (reg > 6) {
/* Assembler bug. The parser shouldn't pass this value. */
asm_error(ctx, "OFFR-nr too big");
}
if (reg == 6) {
asm_warn(ctx, "Using offset register 6. This register is broken "
"on certain devices. Use off0 to off5 only.");
}
val |= off;
val |= (reg << reg_shift);
break;
default:
asm_error(ctx, "generate_mem_operand() memtype");
}
return val;
}
static void generate_operand(struct assembler_context *ctx,
const struct operand *oper,
struct out_operand *out)
{
out->type = OUTOPER_NORMAL;
switch (oper->type) {
case OPER_IMM:
out->u.operand = generate_imm_operand(ctx, oper->u.imm);
break;
case OPER_REG:
out->u.operand = generate_reg_operand(ctx, oper->u.reg);
break;
case OPER_MEM:
out->u.operand = generate_mem_operand(ctx, oper->u.mem);
break;
case OPER_LABEL:
out->type = OUTOPER_LABELREF;
out->u.label = oper->u.label;
break;
case OPER_ADDR:
out->u.operand = oper->u.addr->addr;
break;
case OPER_RAW:
out->u.operand = oper->u.raw;
break;
default:
asm_error(ctx, "generate_operand() operstate");
}
}
static struct code_output * do_assemble_insn(struct assembler_context *ctx,
struct instruction *insn,
unsigned int opcode)
{
unsigned int i;
struct operlist *ol;
int nr_oper = 0;
uint64_t code = 0;
struct code_output *out;
struct label *labelref = NULL;
struct operand *oper;
int have_spr_operand = 0;
int have_mem_operand = 0;
out = xmalloc(sizeof(*out));
INIT_LIST_HEAD(&out->list);
out->opcode = opcode;
ol = insn->operands;
if (ARRAY_SIZE(out->operands) > ARRAY_SIZE(ol->oper))
asm_error(ctx, "Internal operand array confusion");
for (i = 0; i < ARRAY_SIZE(out->operands); i++) {
oper = ol->oper[i];
if (!oper)
continue;
/* If this is an INPUT operand (first or second), we must
* make sure that not both are accessing SPR or MEMORY.
* The device only supports one SPR or MEMORY operand in
* the input operands. */
if ((i == 0) || (i == 1)) {
if ((oper->type == OPER_REG) &&
(oper->u.reg->type == SPR)) {
if (have_spr_operand)
asm_error(ctx, "Multiple SPR input operands in one instruction");
have_spr_operand = 1;
}
if (oper->type == OPER_MEM) {
if (have_mem_operand)
asm_error(ctx, "Multiple MEMORY input operands in on instruction");
have_mem_operand = 1;
}
}
generate_operand(ctx, oper, &out->operands[i]);
nr_oper++;
}
if (nr_oper != 3)
asm_error(ctx, "Internal error: nr_oper at "
"lowlevel do_assemble_insn");
list_add_tail(&out->list, &ctx->output);
return out;
}
static void do_assemble_ret(struct assembler_context *ctx,
struct instruction *insn,
unsigned int opcode)
{
struct code_output *out;
/* Get the previous instruction and check whether it
* is a jump instruction. */
list_for_each_entry_reverse(out, &ctx->output, list) {
/* Search the last insn. */
if (out->type == OUT_INSN) {
if (out->is_jump_insn) {
asm_warn(ctx, "RET instruction directly after "
"jump instruction. The hardware won't like this.");
}
break;
}
}
do_assemble_insn(ctx, insn, opcode);
}
static unsigned int merge_ext_into_opcode(struct assembler_context *ctx,
unsigned int opbase,
struct instruction *insn)
{
struct operlist *ol;
unsigned int opcode;
unsigned int mask, shift;
ol = insn->operands;
opcode = opbase;
mask = ol->oper[0]->u.raw;
if (mask & ~0xF)
asm_error(ctx, "opcode MASK extension too big (> 0xF)");
shift = ol->oper[1]->u.raw;
if (shift & ~0xF)
asm_error(ctx, "opcode SHIFT extension too big (> 0xF)");
opcode |= (mask << 4);
opcode |= shift;
ol->oper[0] = ol->oper[2];
ol->oper[1] = ol->oper[3];
ol->oper[2] = ol->oper[4];
return opcode;
}
static unsigned int merge_external_jmp_into_opcode(struct assembler_context *ctx,
unsigned int opbase,
struct instruction *insn)
{
struct operand *fake;
struct registr *fake_reg;
struct operand *target;
struct operlist *ol;
unsigned int cond;
unsigned int opcode;
ol = insn->operands;
opcode = opbase;
cond = ol->oper[0]->u.imm->imm;
if (cond & ~0xFF)
asm_error(ctx, "External jump condition value too big (> 0xFF)");
opcode |= cond;
target = ol->oper[1];
memset(ol->oper, 0, sizeof(ol->oper));
/* This instruction has two fake r0 operands
* at position 0 and 1. */
fake = xmalloc(sizeof(*fake));
fake_reg = xmalloc(sizeof(*fake_reg));
fake->type = OPER_REG;
fake->u.reg = fake_reg;
fake_reg->type = GPR;
fake_reg->nr = 0;
ol->oper[0] = fake;
ol->oper[1] = fake;
ol->oper[2] = target;
return opcode;
}
static void assemble_instruction(struct assembler_context *ctx,
struct instruction *insn);
static void emulate_mov_insn(struct assembler_context *ctx,
struct instruction *insn)
{
struct instruction em_insn;
struct operlist em_ol;
struct operand em_op_shift;
struct operand em_op_mask;
struct operand em_op_x;
struct operand em_op_y;
struct immediate em_imm_x;
struct immediate em_imm_y;
struct operand *in, *out;
unsigned int tmp;
/* This is a pseudo-OP. We emulate it by OR or ORX */
in = insn->operands->oper[0];
out = insn->operands->oper[1];
em_insn.op = OP_OR;
em_ol.oper[0] = in;
em_imm_x.imm = 0;
em_op_x.type = OPER_IMM;
em_op_x.u.imm = &em_imm_x;
em_ol.oper[1] = &em_op_x;
em_ol.oper[2] = out;
if (in->type == OPER_IMM) {
tmp = in->u.imm->imm;
if (!is_possible_imm(tmp))
asm_error(ctx, "MOV operand 0x%X > 16bit", tmp);
if (!is_valid_imm(ctx, tmp)) {
/* Immediate too big for plain OR */
em_insn.op = OP_ORX;
em_op_mask.type = OPER_RAW;
em_op_mask.u.raw = 0x7;
em_op_shift.type = OPER_RAW;
em_op_shift.u.raw = 0x8;
em_imm_x.imm = (tmp & 0xFF00) >> 8;
em_op_x.type = OPER_IMM;
em_op_x.u.imm = &em_imm_x;
em_imm_y.imm = (tmp & 0x00FF);
em_op_y.type = OPER_IMM;
em_op_y.u.imm = &em_imm_y;
em_ol.oper[0] = &em_op_mask;
em_ol.oper[1] = &em_op_shift;
em_ol.oper[2] = &em_op_x;
em_ol.oper[3] = &em_op_y;
em_ol.oper[4] = out;
}
}
em_insn.operands = &em_ol;
assemble_instruction(ctx, &em_insn); /* recurse */
}
static void emulate_jmp_insn(struct assembler_context *ctx,
struct instruction *insn)
{
struct instruction em_insn;
struct operlist em_ol;
struct immediate em_condition;
struct operand em_cond_op;
/* This is a pseudo-OP. We emulate it with
* JEXT 0x7F, target */
em_insn.op = OP_JEXT;
em_condition.imm = 0x7F; /* Ext cond: Always true */
em_cond_op.type = OPER_IMM;
em_cond_op.u.imm = &em_condition;
em_ol.oper[0] = &em_cond_op;
em_ol.oper[1] = insn->operands->oper[0]; /* Target */
em_insn.operands = &em_ol;
assemble_instruction(ctx, &em_insn); /* recurse */
}
static void emulate_jand_insn(struct assembler_context *ctx,
struct instruction *insn,
int inverted)
{
struct code_output *out;
struct instruction em_insn;
struct operlist em_ol;
struct operand em_op_shift;
struct operand em_op_mask;
struct operand em_op_y;
struct immediate em_imm;
struct operand *oper0, *oper1, *oper2;
struct operand *imm_oper = NULL;
unsigned int tmp;
int first_bit, last_bit;
oper0 = insn->operands->oper[0];
oper1 = insn->operands->oper[1];
oper2 = insn->operands->oper[2];
if (oper0->type == OPER_IMM)
imm_oper = oper0;
if (oper1->type == OPER_IMM)
imm_oper = oper1;
if (oper0->type == OPER_IMM && oper1->type == OPER_IMM)
imm_oper = NULL;
if (imm_oper) {
/* We have a single immediate operand.
* Check if it's representable by a normal JAND insn.
*/
tmp = imm_oper->u.imm->imm;
if (!is_valid_imm(ctx, tmp)) {
/* Nope, this must be emulated by JZX/JNZX */
if (!is_contiguous_bitmask(tmp)) {
asm_error(ctx, "Long bitmask 0x%X is not contiguous",
tmp);
}
first_bit = ffs(tmp);
last_bit = ffs(~(tmp >> (first_bit - 1))) - 1 + first_bit - 1;
if (inverted)
em_insn.op = OP_JZX;
else
em_insn.op = OP_JNZX;
em_op_shift.type = OPER_RAW;
em_op_shift.u.raw = first_bit - 1;
em_op_mask.type = OPER_RAW;
em_op_mask.u.raw = last_bit - first_bit;
em_imm.imm = 0;
em_op_y.type = OPER_IMM;
em_op_y.u.imm = &em_imm;
em_ol.oper[0] = &em_op_mask;
em_ol.oper[1] = &em_op_shift;
if (oper0->type != OPER_IMM)
em_ol.oper[2] = oper0;
else
em_ol.oper[2] = oper1;
em_ol.oper[3] = &em_op_y;
em_ol.oper[4] = oper2;
em_insn.operands = &em_ol;
assemble_instruction(ctx, &em_insn); /* recurse */
return;
}
}
/* Do a normal JAND/JNAND instruction */
if (inverted)
out = do_assemble_insn(ctx, insn, 0x040 | 0x1);
else
out = do_assemble_insn(ctx, insn, 0x040);
out->is_jump_insn = 1;
}
static void assemble_instruction(struct assembler_context *ctx,
struct instruction *insn)
{
struct code_output *out;
unsigned int opcode;
switch (insn->op) {
case OP_MUL:
do_assemble_insn(ctx, insn, 0x101);
break;
case OP_ADD:
do_assemble_insn(ctx, insn, 0x1C0);
break;
case OP_ADDSC:
do_assemble_insn(ctx, insn, 0x1C2);
break;
case OP_ADDC:
do_assemble_insn(ctx, insn, 0x1C1);
break;
case OP_ADDSCC:
do_assemble_insn(ctx, insn, 0x1C3);
break;
case OP_SUB:
do_assemble_insn(ctx, insn, 0x1D0);
break;
case OP_SUBSC:
do_assemble_insn(ctx, insn, 0x1D2);
break;
case OP_SUBC:
do_assemble_insn(ctx, insn, 0x1D1);
break;
case OP_SUBSCC:
do_assemble_insn(ctx, insn, 0x1D3);
break;
case OP_SRA:
do_assemble_insn(ctx, insn, 0x130);
break;
case OP_OR:
do_assemble_insn(ctx, insn, 0x160);
break;
case OP_AND:
do_assemble_insn(ctx, insn, 0x140);
break;
case OP_XOR:
do_assemble_insn(ctx, insn, 0x170);
break;
case OP_SR:
do_assemble_insn(ctx, insn, 0x120);
break;
case OP_SRX:
opcode = merge_ext_into_opcode(ctx, 0x200, insn);
do_assemble_insn(ctx, insn, opcode);
break;
case OP_SL:
do_assemble_insn(ctx, insn, 0x110);
break;
case OP_RL:
do_assemble_insn(ctx, insn, 0x1A0);
break;
case OP_RR:
do_assemble_insn(ctx, insn, 0x1B0);
break;
case OP_NAND:
do_assemble_insn(ctx, insn, 0x150);
break;
case OP_ORX:
opcode = merge_ext_into_opcode(ctx, 0x300, insn);
do_assemble_insn(ctx, insn, opcode);
break;
case OP_MOV:
emulate_mov_insn(ctx, insn);
return;
case OP_JMP:
emulate_jmp_insn(ctx, insn);
return;
case OP_JAND:
emulate_jand_insn(ctx, insn, 0);
return;
case OP_JNAND:
emulate_jand_insn(ctx, insn, 1);
return;
case OP_JS:
out = do_assemble_insn(ctx, insn, 0x050);
out->is_jump_insn = 1;
break;
case OP_JNS:
out = do_assemble_insn(ctx, insn, 0x050 | 0x1);
out->is_jump_insn = 1;
break;
case OP_JE:
out = do_assemble_insn(ctx, insn, 0x0D0);
out->is_jump_insn = 1;
break;
case OP_JNE:
out = do_assemble_insn(ctx, insn, 0x0D0 | 0x1);
out->is_jump_insn = 1;
break;
case OP_JLS:
out = do_assemble_insn(ctx, insn, 0x0D2);
out->is_jump_insn = 1;
break;
case OP_JGES:
out = do_assemble_insn(ctx, insn, 0x0D2 | 0x1);
out->is_jump_insn = 1;
break;
case OP_JGS:
out = do_assemble_insn(ctx, insn, 0x0D4);
out->is_jump_insn = 1;
break;
case OP_JLES:
out = do_assemble_insn(ctx, insn, 0x0D4 | 0x1);
out->is_jump_insn = 1;
break;
case OP_JL:
out = do_assemble_insn(ctx, insn, 0x0DA);
out->is_jump_insn = 1;
break;
case OP_JGE:
out = do_assemble_insn(ctx, insn, 0x0DA | 0x1);
out->is_jump_insn = 1;
break;
case OP_JG:
out = do_assemble_insn(ctx, insn, 0x0DC);
break;
case OP_JLE:
out = do_assemble_insn(ctx, insn, 0x0DC | 0x1);
out->is_jump_insn = 1;
break;
case OP_JDN:
out = do_assemble_insn(ctx, insn, 0x0D6);
out->is_jump_insn = 1;
break;
case OP_JDPZ:
out = do_assemble_insn(ctx, insn, 0x0D6 | 0x1);
out->is_jump_insn = 1;
break;
case OP_JDP:
out = do_assemble_insn(ctx, insn, 0x0D8);
out->is_jump_insn = 1;
break;
case OP_JDNZ:
out = do_assemble_insn(ctx, insn, 0x0D8 | 0x1);
out->is_jump_insn = 1;
break;
case OP_JZX:
opcode = merge_ext_into_opcode(ctx, 0x400, insn);
out = do_assemble_insn(ctx, insn, opcode);
out->is_jump_insn = 1;
break;
case OP_JNZX:
opcode = merge_ext_into_opcode(ctx, 0x500, insn);
out = do_assemble_insn(ctx, insn, opcode);
out->is_jump_insn = 1;
break;
case OP_JEXT:
opcode = merge_external_jmp_into_opcode(ctx, 0x700, insn);
out = do_assemble_insn(ctx, insn, opcode);
out->is_jump_insn = 1;
break;
case OP_JNEXT:
opcode = merge_external_jmp_into_opcode(ctx, 0x600, insn);
out = do_assemble_insn(ctx, insn, opcode);
out->is_jump_insn = 1;
break;
case OP_CALL:
if (ctx->arch != 5)
asm_error(ctx, "'call' instruction is only supported on arch 5");
do_assemble_insn(ctx, insn, 0x002);
break;
case OP_CALLS:
if (ctx->arch != 15)
asm_error(ctx, "'calls' instruction is only supported on arch 15");
do_assemble_insn(ctx, insn, 0x004);
break;
case OP_RET:
if (ctx->arch != 5)
asm_error(ctx, "'ret' instruction is only supported on arch 5");
do_assemble_ret(ctx, insn, 0x003);
break;
case OP_RETS:
if (ctx->arch != 15)
asm_error(ctx, "'rets' instruction is only supported on arch 15");
do_assemble_insn(ctx, insn, 0x005);
break;
case OP_TKIPH:
case OP_TKIPHS:
case OP_TKIPL:
case OP_TKIPLS:
do_assemble_insn(ctx, insn, 0x1E0);
break;
case OP_NAP:
do_assemble_insn(ctx, insn, 0x001);
break;
case RAW_CODE:
do_assemble_insn(ctx, insn, insn->opcode);
break;
default:
asm_error(ctx, "Unknown op");
}
}
static void assemble_instructions(struct assembler_context *ctx)
{
struct statement *s;
struct instruction *insn;
struct code_output *out;
if (ctx->start_label) {
/* Generate a jump instruction at offset 0 to
* jump to the code start.
*/
struct instruction sjmp;
struct operlist ol;
struct operand oper;
oper.type = OPER_LABEL;
oper.u.label = ctx->start_label;
ol.oper[0] = &oper;
sjmp.op = OP_JMP;
sjmp.operands = &ol;
assemble_instruction(ctx, &sjmp);
out = list_entry(ctx->output.next, struct code_output, list);
out->is_start_insn = 1;
}
for_each_statement(ctx, s) {
switch (s->type) {
case STMT_INSN:
ctx->cur_stmt = s;
insn = s->u.insn;
assemble_instruction(ctx, insn);
break;
case STMT_LABEL:
out = xmalloc(sizeof(*out));
INIT_LIST_HEAD(&out->list);
out->type = OUT_LABEL;
out->labelname = s->u.label->name;
list_add_tail(&out->list, &ctx->output);
break;
case STMT_ASMDIR:
break;
}
} for_each_statement_end(ctx, s);
}
/* Resolve a label reference to the address it points to. */
static int get_labeladdress(struct assembler_context *ctx,
struct code_output *this_insn,
struct label *labelref)
{
struct code_output *c;
bool found = 0;
int address = -1;
switch (labelref->direction) {
case LABELREF_ABSOLUTE:
list_for_each_entry(c, &ctx->output, list) {
if (c->type != OUT_LABEL)
continue;
if (strcmp(c->labelname, labelref->name) != 0)
continue;
if (found) {
asm_error(ctx, "Ambiguous label reference \"%s\"",
labelref->name);
}
found = 1;
address = c->address;
}
break;
case LABELREF_RELATIVE_BACK:
for (c = list_entry(this_insn->list.prev, typeof(*c), list);
&c->list != &ctx->output;
c = list_entry(c->list.prev, typeof(*c), list)) {
if (c->type != OUT_LABEL)
continue;
if (strcmp(c->labelname, labelref->name) == 0) {
/* Found */
address = c->address;
break;
}
}
break;
case LABELREF_RELATIVE_FORWARD:
for (c = list_entry(this_insn->list.next, typeof(*c), list);
&c->list != &ctx->output;
c = list_entry(c->list.next, typeof(*c), list)) {
if (c->type != OUT_LABEL)
continue;
if (strcmp(c->labelname, labelref->name) == 0) {
/* Found */
address = c->address;
break;
}
}
break;
}
return address;
}
static void resolve_labels(struct assembler_context *ctx)
{
struct code_output *c;
int addr;
unsigned int i;
unsigned int current_address;
/* Calculate the absolute addresses for each instruction. */
recalculate_addresses:
current_address = 0;
list_for_each_entry(c, &ctx->output, list) {
switch (c->type) {
case OUT_INSN:
c->address = current_address;
current_address++;
break;
case OUT_LABEL:
c->address = current_address;
break;
}
}
/* Resolve the symbolic label references. */
list_for_each_entry(c, &ctx->output, list) {
switch (c->type) {
case OUT_INSN:
if (c->is_start_insn) {
/* If the first %start-jump jumps to 001, we can
* optimize it away, as it's unneeded.
*/
i = 2;
if (c->operands[i].type != OUTOPER_LABELREF)
asm_error(ctx, "Internal error, %%start insn oper 2 not labelref");
if (c->operands[i].u.label->direction != LABELREF_ABSOLUTE)
asm_error(ctx, "%%start label reference not absolute");
addr = get_labeladdress(ctx, c, c->operands[i].u.label);
if (addr < 0)
goto does_not_exist;
if (addr == 1) {
list_del(&c->list); /* Kill it */
goto recalculate_addresses;
}
}
for (i = 0; i < ARRAY_SIZE(c->operands); i++) {
if (c->operands[i].type != OUTOPER_LABELREF)
continue;
addr = get_labeladdress(ctx, c, c->operands[i].u.label);
if (addr < 0)
goto does_not_exist;
c->operands[i].u.operand = addr;
if (i != 2) {
/* Is not a jump target.
* Make it be an immediate */
if (ctx->arch == 5)
c->operands[i].u.operand |= 0xC00;
else if (ctx->arch == 15)
c->operands[i].u.operand |= 0xC00 << 1;
else
asm_error(ctx, "Internal error: label res imm");
}
}
break;
case OUT_LABEL:
break;
}
}
return;
does_not_exist:
asm_error(ctx, "Label \"%s\" does not exist",
c->operands[i].u.label->name);
}
static void emit_code(struct assembler_context *ctx)
{
FILE *fd;
const char *fn;
struct code_output *c;
uint64_t code;
unsigned char outbuf[8];
unsigned int insn_count = 0, insn_count_limit;
struct fw_header hdr;
fn = outfile_name;
fd = fopen(fn, "w+");
if (!fd) {
fprintf(stderr, "Could not open microcode output file \"%s\"\n", fn);
exit(1);
}
if (IS_VERBOSE_DEBUG)
printf("\nCode:\n");
list_for_each_entry(c, &ctx->output, list) {
switch (c->type) {
case OUT_INSN:
insn_count++;
break;
default:
break;
}
}
switch (cmdargs.outformat) {
case FMT_RAW_LE32:
case FMT_RAW_BE32:
/* Nothing */
break;
case FMT_B43:
memset(&hdr, 0, sizeof(hdr));
hdr.type = FW_TYPE_UCODE;
hdr.ver = FW_HDR_VER;
hdr.size = cpu_to_be32(8 * insn_count);
if (fwrite(&hdr, sizeof(hdr), 1, fd) != 1) {
fprintf(stderr, "Could not write microcode outfile\n");
exit(1);
}
break;
}
switch (ctx->arch) {
case 5:
insn_count_limit = NUM_INSN_LIMIT_R5;
break;
case 15:
insn_count_limit = ~0; //FIXME limit currently unknown.
break;
default:
asm_error(ctx, "Internal error: emit_code unknown arch\n");
}
if (insn_count > insn_count_limit)
asm_warn(ctx, "Generating more than %u instructions. This "
"will overflow the device microcode memory.",
insn_count_limit);
list_for_each_entry(c, &ctx->output, list) {
switch (c->type) {
case OUT_INSN:
if (IS_VERBOSE_DEBUG) {
printf("%03X %04X,%04X,%04X\n",
c->opcode,
c->operands[0].u.operand,
c->operands[1].u.operand,
c->operands[2].u.operand);
}
switch (ctx->arch) {
case 5:
code = 0;
code |= ((uint64_t)c->operands[2].u.operand);
code |= ((uint64_t)c->operands[1].u.operand) << 12;
code |= ((uint64_t)c->operands[0].u.operand) << 24;
code |= ((uint64_t)c->opcode) << 36;
break;
case 15:
code = 0;
code |= ((uint64_t)c->operands[2].u.operand);
code |= ((uint64_t)c->operands[1].u.operand) << 13;
code |= ((uint64_t)c->operands[0].u.operand) << 26;
code |= ((uint64_t)c->opcode) << 39;
break;
default:
asm_error(ctx, "No emit format for arch %u",
ctx->arch);
}
switch (cmdargs.outformat) {
case FMT_B43:
case FMT_RAW_BE32:
code = ((code & (uint64_t)0xFFFFFFFF00000000ULL) >> 32) |
((code & (uint64_t)0x00000000FFFFFFFFULL) << 32);
outbuf[0] = (code & (uint64_t)0xFF00000000000000ULL) >> 56;
outbuf[1] = (code & (uint64_t)0x00FF000000000000ULL) >> 48;
outbuf[2] = (code & (uint64_t)0x0000FF0000000000ULL) >> 40;
outbuf[3] = (code & (uint64_t)0x000000FF00000000ULL) >> 32;
outbuf[4] = (code & (uint64_t)0x00000000FF000000ULL) >> 24;
outbuf[5] = (code & (uint64_t)0x0000000000FF0000ULL) >> 16;
outbuf[6] = (code & (uint64_t)0x000000000000FF00ULL) >> 8;
outbuf[7] = (code & (uint64_t)0x00000000000000FFULL) >> 0;
break;
case FMT_RAW_LE32:
outbuf[7] = (code & (uint64_t)0xFF00000000000000ULL) >> 56;
outbuf[6] = (code & (uint64_t)0x00FF000000000000ULL) >> 48;
outbuf[5] = (code & (uint64_t)0x0000FF0000000000ULL) >> 40;
outbuf[4] = (code & (uint64_t)0x000000FF00000000ULL) >> 32;
outbuf[3] = (code & (uint64_t)0x00000000FF000000ULL) >> 24;
outbuf[2] = (code & (uint64_t)0x0000000000FF0000ULL) >> 16;
outbuf[1] = (code & (uint64_t)0x000000000000FF00ULL) >> 8;
outbuf[0] = (code & (uint64_t)0x00000000000000FFULL) >> 0;
break;
}
if (fwrite(&outbuf, ARRAY_SIZE(outbuf), 1, fd) != 1) {
fprintf(stderr, "Could not write microcode outfile\n");
exit(1);
}
break;
case OUT_LABEL:
break;
}
}
if (cmdargs.print_sizes) {
printf("%s: text = %u instructions (%u bytes)\n",
fn, insn_count,
(unsigned int)(insn_count * sizeof(uint64_t)));
}
fclose(fd);
}
static void assemble(void)
{
struct assembler_context ctx;
memset(&ctx, 0, sizeof(ctx));
INIT_LIST_HEAD(&ctx.output);
eval_directives(&ctx);
assemble_instructions(&ctx);
resolve_labels(&ctx);
emit_code(&ctx);
}
static void initialize(void)
{
INIT_LIST_HEAD(&infile.sl);
INIT_LIST_HEAD(&infile.ivals);
#if YYDEBUG
if (IS_INSANE_DEBUG)
yydebug = 1;
else
yydebug = 0;
#endif /* YYDEBUG */
}
int main(int argc, char **argv)
{
int err, res = 1;
err = parse_args(argc, argv);
if (err < 0)
goto out;
if (err > 0) {
res = 0;
goto out;
}
err = open_input_file();
if (err)
goto out;
initialize();
yyparse();
assemble();
assemble_initvals();
close_input_file();
res = 0;
out:
/* Lazyman simply leaks all allocated memory. */
return res;
}
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