firmware_load.c-Dateireferenz

#include <stdlib.h>
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#include <time.h>
#include <stdarg.h>
#include "dancingbits.h"
#include "stubs_load.h"
#include "firmware_load.h"

Include-Abhängigkeitsdiagramm für firmware_load.c:

gehe zum Quellcode dieser Datei

Funktionen
void	error (char *, int)
void	usage (char *err)
void	addBufRange (firmware *fw, int o, int l)
void	findRanges (firmware *fw)
int	idx_valid (firmware *fw, int i)
uint32_t	idx2adr (firmware *fw, int idx)
int	adr2idx (firmware *fw, uint32_t adr)
char *	adr2ptr (firmware *fw, uint32_t adr)
int	idxcorr (firmware *fw, int idx)
void	set_ignore_errors (int n)
uint32_t *	fwadr (firmware *fw, int i)
uint32_t	fwval (firmware *fw, int i)
int	fwRd (firmware *fw, int i)
int	fwRn (firmware *fw, int i)
int	fwRnMOV (firmware *fw, int i)
int	fwOp2 (firmware *fw, int i)
uint32_t	LDR2adr (firmware *fw, int offset)
uint32_t	LDR2idx (firmware *fw, int offset)
uint32_t	LDR2val (firmware *fw, int offset)
uint32_t	ADR2adr (firmware *fw, int offset)
uint32_t	ALUop2 (firmware *fw, int offset)
uint32_t	ALUop2a (firmware *fw, int offset)
int	idxFollowBranch (firmware *fw, int fidx, int offset)
uint32_t	followBranch (firmware *fw, uint32_t fadr, int offset)
uint32_t	followBranch2 (firmware *fw, uint32_t fadr, int offset)
int	isLDR_PC (firmware *fw, int offset)
int	isLDR_PC_cond (firmware *fw, int offset)
int	isLDR_SP (firmware *fw, int offset)
int	isLDR (firmware *fw, int offset)
int	isLDR_cond (firmware *fw, int offset)
int	isADR_PC (firmware *fw, int offset)
int	isADR_PC_cond (firmware *fw, int offset)
int	isADR (firmware *fw, int offset)
int	isLDMFD (firmware *fw, int offset)
int	isLDMFD_PC (firmware *fw, int offset)
int	isSTMFD (firmware *fw, int offset)
int	isSTMFD_LR (firmware *fw, int offset)
int	isSTR (firmware *fw, int offset)
int	isSTR_cond (firmware *fw, int offset)
int	isBX (firmware *fw, int offset)
int	isBX_cond (firmware *fw, int offset)
int	isBX_LR (firmware *fw, int offset)
int	isBLX (firmware *fw, int offset)
int	isBL (firmware *fw, int offset)
int	isBL_cond (firmware *fw, int offset)
int	isBLEQ (firmware *fw, int offset)
int	isB (firmware *fw, int offset)
int	isBorBL (firmware *fw, int offset)
int	isCMP (firmware *fw, int offset)
int	isMOV (firmware *fw, int offset)
int	isMOV_immed (firmware *fw, int offset)
int	isORR (firmware *fw, int offset)
int	isADD (firmware *fw, int offset)
int	isSUB (firmware *fw, int offset)
int	isASCIIstring (firmware *fw, uint32_t adr)
int	find_Nth_str (firmware *fw, char *str, int N)
int	find_str (firmware *fw, char *str)
uint32_t	find_str_bytes (firmware *fw, char *str)
int	find_inst (firmware *fw, int(*inst)(firmware *, int), int idx, int len)
int	find_inst_rev (firmware *fw, int(*inst)(firmware *, int), int idx, int len)
int	find_Nth_inst (firmware *fw, int(*inst)(firmware *, int), int idx, int len, int N)
int	find_Nth_inst_rev (firmware *fw, int(*inst)(firmware *, int), int idx, int len, int N)
int	find_strptr_ref (firmware *fw, char *str)
int	find_str_ref (firmware *fw, char *str)
int	find_nxt_str_ref (firmware *fw, int str_adr, int ofst)
int	find_nxt_str_ref_alt (firmware *fw, char *str, int ofst, int limit)
int	find_BL (firmware *fw, int k, uint32_t v1, __attribute__((unused)) uint32_t v2)
int	find_B (firmware *fw, int k, uint32_t v1, __attribute__((unused)) uint32_t v2)
int	search_fw (firmware *fw, int(*func)(firmware *, int, uint32_t, uint32_t), uint32_t v1, uint32_t v2, int len)
int	search_fw_bytes (firmware *fw, int(*func)(firmware *, int))
void	load_firmware (firmware *fw, const char *filename, const char *base_addr, const char *alt_base_addr, int os_type)

Variablen
static int	ignore_errors = 0

Dokumentation der Funktionen

void addBufRange	(	firmware *	fw,
		int	o,
		int	l
	)

Definiert in Zeile 53 der Datei firmware_load.c.

{
    BufRange *n = malloc(sizeof(BufRange));
    n->p = fw->buf + o;
    n->off = o;
    n->len = l;
    n->next = 0;
    if (fw->br == 0)
    {
        fw->br = n;
    }
    else
    {
        fw->last->next = n;
    }
    fw->last = n;
}

uint32_t ADR2adr	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 309 der Datei firmware_load.c.

{
    uint32_t inst = fwval(fw,offset);
    int rot = 32 - ((inst & 0xF00) >> 7);
    int offst = (inst & 0xFF) <<rot;
    uint32_t fadr = 0;
    switch (inst & 0x01E00000)
    {
        case 0x00400000:    // SUB
            fadr = idx2adr(fw,offset+2)-offst;
            break;
        case 0x00800000:    // ADD
            fadr = idx2adr(fw,offset+2)+offst;
            break;
        case 0x01A00000:    // MOV
            //fprintf(stderr,"***** ADR2adr MOV\n");
            break;
        case 0x01E00000:    // MVN
            //fprintf(stderr,"***** ADR2adr MVN\n");
            break;
    }
    return fadr;
}

int adr2idx	(	firmware *	fw,
		uint32_t	adr
	)

Definiert in Zeile 165 der Datei firmware_load.c.

{
    if (adr < fw->base)
        return -((fw->base - adr) >> 2);
    else
        return (adr - fw->base) >> 2;
}

char* adr2ptr	(	firmware *	fw,
		uint32_t	adr
	)

Definiert in Zeile 174 der Datei firmware_load.c.

{
    if ((fw->dryos_ver >= 51) && (fw->alt_base) && (adr >= fw->alt_base))
    {
        return ((char*)fw->buf) + (adr - fw->alt_base);
    }
    if ((fw->dryos_ver >= 50) && (adr < fw->base))
    {
        adr = (adr - fw->base2) + fw->base_copied;
    }
    return ((char*)fw->buf) + (adr - fw->base);
}

uint32_t ALUop2	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 334 der Datei firmware_load.c.

{
    uint32_t inst = fwval(fw,offset);
    int rot = 32 - ((inst & 0xF00) >> 7);
    int offst = (inst & 0xFF) <<rot;
    uint32_t fadr = 0;
    switch (inst & 0x03E00000)
    {
        case 0x02400000:    // SUB Immed
        case 0x02800000:    // ADD Immed
        case 0x03400000:    // CMP Immed
        case 0x03A00000:    // MOV Immed
        case 0x03C00000:    // BIC Immed
            fadr = offst;
            break;
    }
    return fadr;
}

uint32_t ALUop2a	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 354 der Datei firmware_load.c.

{
    uint32_t inst = fwval(fw,offset);
    uint32_t rot = (inst>>7)&0x1e;
    uint32_t imm8 = inst & 0xff;
    uint32_t offst = (imm8>>rot) | (imm8<<(32-rot));
    uint32_t fadr = 0;
    switch (inst & 0x03E00000)
    {
        case 0x02400000:    // SUB Immed
        case 0x02800000:    // ADD Immed
        case 0x03A00000:    // MOV Immed
        case 0x03C00000:    // BIC Immed
        case 0x03800000:    // ORR Immed
            fadr = offst;
            break;
    }
    return fadr;
}

void error	(	char *	,
		int
	)

Definiert in Zeile 69 der Datei finsig_dryos.c.

{
    bprintf(fmt, n);
    write_output();
    exit(1);
}

int find_B	(	firmware *	fw,
		int	k,
		uint32_t	v1,
		__attribute__((unused)) uint32_t	v2
	)

Definiert in Zeile 864 der Datei firmware_load.c.

{
    if (isB(fw,k))
    {
        uint32_t n = idxFollowBranch(fw, k, 0x00000001);
        if (n == v1)
            return k;
    }
    return 0;
}

int find_BL	(	firmware *	fw,
		int	k,
		uint32_t	v1,
		__attribute__((unused)) uint32_t	v2
	)

Definiert in Zeile 851 der Datei firmware_load.c.

{
    if (isBL(fw,k))
    {
        uint32_t n = idxFollowBranch(fw, k, 0x01000001);
        if (n == v1)
            return k;
    }
    return 0;
}

int find_inst	(	firmware *	fw,
		int(*)(firmware *, int)	inst,
		int	idx,
		int	len
	)

Definiert in Zeile 692 der Datei firmware_load.c.

{
    int k;
    for (k = idx; (k < fw->size) && (k < idx + len); k++)
    {
        if (inst(fw, k))
            return k;
    }
    return -1;
}

int find_inst_rev	(	firmware *	fw,
		int(*)(firmware *, int)	inst,
		int	idx,
		int	len
	)

Definiert in Zeile 705 der Datei firmware_load.c.

{
    int k;
    for (k = idx; (k > 0) && (k > idx - len); k--)
    {
        if (inst(fw, k))
            return k;
    }
    return -1;
}

int find_Nth_inst	(	firmware *	fw,
		int(*)(firmware *, int)	inst,
		int	idx,
		int	len,
		int	N
	)

Definiert in Zeile 718 der Datei firmware_load.c.

{
    int k;
    for (k = idx; (k < fw->size) && (k < idx + len); k++)
    {
        if (inst(fw, k))
            N--;
        if (N <= 0)
            return k;
    }
    return -1;
}

int find_Nth_inst_rev	(	firmware *	fw,
		int(*)(firmware *, int)	inst,
		int	idx,
		int	len,
		int	N
	)

Definiert in Zeile 733 der Datei firmware_load.c.

{
    int k;
    for (k = idx; (k > 0) && (k > idx - len); k--)
    {
        if (inst(fw, k))
            N--;
        if (N <= 0)
            return k;
    }
    return -1;
}

int find_Nth_str	(	firmware *	fw,
		char *	str,
		int	N
	)

Definiert in Zeile 642 der Datei firmware_load.c.

{
    int nlen = strlen(str);
    uint32_t nm0 = *((uint32_t*)str);
    uint32_t *p;
    int j;

    BufRange *br = fw->br;
    while (br)
    {
        for (p = br->p, j = 0; j < br->len - nlen/4; j++, p++)
        {
            if ((nm0 == *p) && ((nlen<=4) || (memcmp(p+1,str+4,nlen-4) == 0)) )
            {
                if (--N == 0)
                    return j+br->off;
            }
        }
        br = br->next;
    }

    return -1;
}

int find_nxt_str_ref	(	firmware *	fw,
		int	str_adr,
		int	ofst
	)

Definiert in Zeile 808 der Datei firmware_load.c.

{
    if (str_adr >= fw->lowest_idx)
    {
        int k;
        uint32_t sadr = idx2adr(fw,str_adr);        // string address
        for (k=ofst+1; k<fw->size; k++)
        {
            if (isADR_PC_cond(fw,k) && (ADR2adr(fw,k) == sadr))
            {
                return k;
            }
            else if (isLDR_PC_cond(fw,k) && (LDR2val(fw,k) == sadr))
            {
                return k;
            }
        }
    }
    return -1;
}

int find_nxt_str_ref_alt	(	firmware *	fw,
		char *	str,
		int	ofst,
		int	limit
	)

Definiert in Zeile 830 der Datei firmware_load.c.

{
    int k;
    for (k=ofst; k<ofst+limit; k++)
    {
        if (isADR_PC_cond(fw,k) && idx_valid(fw,adr2idx(fw,ADR2adr(fw,k))) && (strcmp(str,adr2ptr(fw,ADR2adr(fw,k))) == 0))
        {
            return k;
        }
        else if (isLDR_PC_cond(fw,k) && idx_valid(fw,adr2idx(fw,LDR2val(fw,k))) && (strcmp(str,adr2ptr(fw,LDR2val(fw,k))) == 0))
        {
            return k;
        }
    }
    return -1;
}

int find_str	(	firmware *	fw,
		char *	str
	)

Definiert in Zeile 666 der Datei firmware_load.c.

{
    return find_Nth_str(fw, str, 1);
}

uint32_t find_str_bytes	(	firmware *	fw,
		char *	str
	)

Definiert in Zeile 673 der Datei firmware_load.c.

{
    BufRange *p = fw->br;
    while (p)
    {
        int k;
        for (k = p->off*4; k < (p->off + p->len)*4; k++)
        {
            if (strcmp(((char*)fw->buf)+k,str) == 0)
                return fw->base+k;
        }
        p = p->next;
    }

    return 0;
}

int find_str_ref	(	firmware *	fw,
		char *	str
	)

Definiert in Zeile 786 der Datei firmware_load.c.

{
    int k = find_str(fw, str);
    if (k >= fw->lowest_idx)
    {
        uint32_t sadr = idx2adr(fw,k);        // string address
        for (k=0; k<fw->size; k++)
        {
            if (isADR_PC_cond(fw,k) && (ADR2adr(fw,k) == sadr))
            {
                return k;
            }
            else if (isLDR_PC_cond(fw,k) && (LDR2val(fw,k) == sadr))
            {
                return k;
            }
        }
    }
    return -1;
}

int find_strptr_ref	(	firmware *	fw,
		char *	str
	)

Definiert in Zeile 753 der Datei firmware_load.c.

{
    uint32_t sadr = find_str_bytes(fw, str);    // string address
    if (sadr > 0)
    {
        int k;
        for (k=0; k<fw->size; k++)
        {
            if (fwval(fw,k) == sadr)
            {
                uint32_t fadr = idx2adr(fw,k);  // string pointer address
                int j;
                for (j=0; j<fw->size; j++)
                {
                    if (isADR_PC_cond(fw,j) && (ADR2adr(fw,j) == fadr))
                    {
                        return j;
                    }
                    else if (isLDR_PC_cond(fw,j) && (LDR2val(fw,j) == fadr))
                    {
                        return j;
                    }
                }
            }
        }
    }
    return -1;
}

void findRanges

(

firmware *

fw)

Definiert in Zeile 72 der Datei firmware_load.c.

{
    int i, j, k;

    // Find all the valid ranges for checking (skips over large blocks of 0xFFFFFFFF)
    fw->br = 0; fw->last = 0;
    k = -1; j = 0;
    for (i = 0; i < fw->size; i++)
    {
        if (fw->buf[i] == 0xFFFFFFFF)   // Possible start of block to skip
        {
            if (k == -1)            // Mark start of possible skip block
            {
                k = i;
            }
        }
        else                        // Found end of block ?
        {
            if (k != -1)
            {
                if (i - k > 32)     // If block more than 32 words then we want to skip it
                {
                    if (k - j > 8)
                    {
                        // Add a range record for the previous valid range (ignore short ranges)
                        addBufRange(fw,j,k - j);
                    }
                    j = i;          // Reset valid range start to current position
                }
                k = -1;             // Reset marker for skip block
            }
        }
    }
    // Add range for last valid block
    if (k != -1)
    {
        if (k - j > 8)
        {
            addBufRange(fw,j,k - j);
        }
    }
    else
    {
        if (i - j > 8)
        {
            addBufRange(fw,j,i - j);
        }
    }
}

uint32_t followBranch	(	firmware *	fw,
		uint32_t	fadr,
		int	offset
	)

Definiert in Zeile 406 der Datei firmware_load.c.

{
    if (offset)
    {
        uint32_t msk = ~(offset & 0xFF000000);
        uint32_t fidx = adr2idx(fw,fadr);  // function index
        fidx += ((offset & 0x00FFFFFF) - 1);
        uint32_t inst = fwval(fw,fidx);
        if ((inst & (0xFF000000&msk)) == (0xEA000000&msk))  // Branch (B or BL depending on msk)
        {
            int o = inst & 0x00FFFFFF;
            if (o & 0x00800000) o |= 0xFF000000;
            if (idx_valid(fw,fidx+o+2))
                fadr = idx2adr(fw,fidx+o+2);
        }
        else if ((inst & (0xFFFFF000)) == (0xE51FF000))     // LDR PC,=...
        {
            fadr = LDR2val(fw,fidx);
        }
    }
    return fadr;
}

uint32_t followBranch2	(	firmware *	fw,
		uint32_t	fadr,
		int	offset
	)

Definiert in Zeile 430 der Datei firmware_load.c.

{
    fadr = followBranch(fw, fadr, offset);
    if ((offset & 0x00FFFFFF) == 1)
        fadr = followBranch(fw, fadr, offset);
    return fadr;
}

uint32_t* fwadr	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 223 der Datei firmware_load.c.

{
    if ((i >= 0) && (i < fw->size))
        return &fw->buf[i];
    if ((fw->dryos_ver >= 51) && (fw->alt_base) && (i >= fw->size))
    {
        i = ((i * 4) - (fw->alt_base - fw->base)) / 4;
        if ((i >= 0) && (i < fw->size))
            return &fw->buf[i];
    }
    if ((fw->dryos_ver >= 50) && (i < 0))
    {
        i = ((i * 4) + (fw->base - fw->base2)) / 4;
        if ((i >= 0) && (i < fw->size2))
            return &fw->buf2[i];
    }
    if (ignore_errors)
    {
        return &fw->buf[0];
    }
    fprintf(stderr,"Invalid firmware offset %d.\n",i);
    error("\nInvalid firmware offset %d. Possible corrupt firmware or incorrect start address.\n",i);
    return 0;
}

int fwOp2	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 276 der Datei firmware_load.c.

{
    // Operand2
    return (*fwadr(fw,i) & 0x00000FFF);
}

int fwRd	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 255 der Datei firmware_load.c.

{
    // Destination register - Rd
    return (*fwadr(fw,i) & 0x0000F000) >> 12;
}

int fwRn	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 262 der Datei firmware_load.c.

{
    // Source register - Rn
    return (*fwadr(fw,i) & 0x000F0000) >> 16;
}

int fwRnMOV	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 269 der Datei firmware_load.c.

{
    // Source register - Rn
    return (*fwadr(fw,i) & 0x0000000F);
}

uint32_t fwval	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 249 der Datei firmware_load.c.

{
    return *fwadr(fw,i);
}

uint32_t idx2adr	(	firmware *	fw,
		int	idx
	)

Definiert in Zeile 159 der Datei firmware_load.c.

{
    return fw->base + (idx << 2);
}

int idx_valid	(	firmware *	fw,
		int	i
	)

Definiert in Zeile 136 der Datei firmware_load.c.

{
    if ((i >= 0) && (i < fw->size))
        return 1;
    if ((fw->dryos_ver >= 51) && (fw->alt_base) && (i >= fw->size))
    {
        i = ((i * 4) - (fw->alt_base - fw->base)) / 4;
        if ((i >= 0) && (i < fw->size))
            return 1;
    }
    if (fw->dryos_ver >= 50)
    {
        int i2 = ((i * 4) + (fw->base - fw->base2)) / 4;
        if ((i2 >= 0) && (i2 < fw->size2))
            return 1;
        // RAM code can also reference ROM, check for that
        if (idx2adr(fw,i)>=fw->base && idx2adr(fw,i)<(fw->base+fw->size*4))
            return 1;
    }
    return 0;
}

int idxcorr	(	firmware *	fw,
		int	idx
	)

Definiert in Zeile 188 der Datei firmware_load.c.

{
    static int inited = 0;
    static int b2oidx, b2idx;
    if (!inited)
    {
        b2oidx = adr2idx(fw, fw->base_copied);
        b2idx = adr2idx(fw, fw->base2);
        inited = 1;
    }

    if (fw->base2)
    {
        if ((idx >= b2oidx) && (idx < b2oidx + fw->size2))
        {
            idx = idx - b2oidx + b2idx;
        }
    }
    return idx;
}

int idxFollowBranch	(	firmware *	fw,
		int	fidx,
		int	offset
	)

Definiert in Zeile 383 der Datei firmware_load.c.

{
    if (offset)
    {
        uint32_t msk = ~(offset & 0xFF000000);
        fidx += ((offset & 0x00FFFFFF) - 1);
        uint32_t inst = fwval(fw,fidx);
        if ((inst & (0xFF000000&msk)) == (0xEA000000&msk))  // Branch (B or BL depending on msk)
        {
            int o = inst & 0x00FFFFFF;
            if (o & 0x00800000) o |= 0xFF000000;
            fidx = fidx + o + 2;
        }
        else if ((inst & (0xFFFFF000)) == (0xE51FF000))     // LDR PC,=...
        {
            fidx = adr2idx(fw,LDR2val(fw,fidx));
        }
    }
    return fidx;
}

int isADD	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 605 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xfff00000) == 0xe2800000);
}

int isADR	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 485 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFE000000) == 0xE2000000);
}

int isADR_PC	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 473 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFE0F0000) == 0xE20F0000);
}

int isADR_PC_cond	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 479 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0x0E0F0000) == 0x020F0000);
}

int isASCIIstring	(	firmware *	fw,
		uint32_t	adr
	)

Definiert in Zeile 618 der Datei firmware_load.c.

{
    if (idx_valid(fw, adr2idx(fw, adr)))
    {
        unsigned char *p = (unsigned char*)adr2ptr(fw, adr);
        int i;
        for (i = 0; (i < 100) && (p[i] != 0); i++)
        {
            if (!((p[i] == '\r') || (p[i] == '\n') || (p[i] == '\t') || ((p[i] >= 0x20) && (p[i] <= 0x7f))))
            {
                return 0;
            }
        }
        if ((i >= 2) && (p[i] == 0))
            return 1;
    }
    return 0;
}

int isB	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 569 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFF000000) == 0xEA000000);
}

int isBL	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 551 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFF000000) == 0xEB000000);
}

int isBL_cond	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 557 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0x0F000000) == 0x0B000000);
}

int isBLEQ	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 563 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFF000000) == 0x0B000000);
}

int isBLX	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 545 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFFFFF0) == 0xE12FFF30);
}

int isBorBL	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 575 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFE000000) == 0xEA000000);
}

int isBX	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 527 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFFFFF0) == 0xE12FFF10);
}

int isBX_cond	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 533 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0x0FFFFFF0) == 0x012FFF10);
}

int isBX_LR	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 539 der Datei firmware_load.c.

{
    return (fwval(fw,offset) == 0xE12FFF1E);
}

int isCMP	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 581 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFF00000) == 0xE3500000);
}

int isLDMFD	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 491 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFF0000) == 0xE8BD0000);
}

int isLDMFD_PC	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 497 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFF8000) == 0xE8BD8000);
}

int isLDR	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 461 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFE100000) == 0xE4100000);
}

int isLDR_cond	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 467 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0x0E100000) == 0x04100000);
}

int isLDR_PC	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 443 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFE1F0000) == 0xE41F0000);
}

int isLDR_PC_cond	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 449 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0x0E1F0000) == 0x041F0000);
}

int isLDR_SP	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 455 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFF0000) == 0xE59D0000);
}

int isMOV	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 587 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFF00000) == 0xE1A00000);
}

int isMOV_immed	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 593 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFF00000) == 0xE3A00000);
}

int isORR	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 599 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFF00000) == 0xE3800000);
}

int isSTMFD	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 503 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFF0000) == 0xE92D0000);
}

int isSTMFD_LR	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 509 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFFFF4000) == 0xE92D4000);
}

int isSTR	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 515 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xFE100000) == 0xE4000000);
}

int isSTR_cond	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 521 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0x0E100000) == 0x04000000);
}

int isSUB	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 611 der Datei firmware_load.c.

{
    return ((fwval(fw,offset) & 0xfff00000) == 0xe2400000);
}

uint32_t LDR2adr	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 285 der Datei firmware_load.c.

{
    uint32_t inst = fwval(fw,offset);
    int offst = (inst & 0xFFF);
    uint32_t fadr = (inst & 0x00800000)?idx2adr(fw,offset+2)+offst:idx2adr(fw,offset+2)-offst;
    return fadr;
}

uint32_t LDR2idx	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 294 der Datei firmware_load.c.

{
    return adr2idx(fw,LDR2adr(fw,offset));
}

uint32_t LDR2val	(	firmware *	fw,
		int	offset
	)

Definiert in Zeile 300 der Datei firmware_load.c.

{
    return fwval(fw,adr2idx(fw,LDR2adr(fw,offset)));
}

void load_firmware	(	firmware *	fw,
		const char *	filename,
		const char *	base_addr,
		const char *	alt_base_addr,
		int	os_type
	)

Definiert in Zeile 923 der Datei firmware_load.c.

{
    // Open file.
    FILE *f = fopen(filename, "rb");
    int i, j, k;

    if (f == NULL)
    {
        fprintf(stderr,"Error opening %s\n",filename);
        usage("firmware open");
    }

    // these are used regardless of camera generation, have to be initialized here
    fw->buf2 = 0;
    fw->base2 = 0;
    fw->size2 = 0;

    fw->os_type = os_type;

    // File length
    fseek(f,0,SEEK_END);
    fw->size = (ftell(f)+3)/4;
    fseek(f,0,SEEK_SET);

    // Save base addresses
    fw->base = strtoul(base_addr, NULL, 0);
    if (alt_base_addr)
        fw->alt_base = strtoul(alt_base_addr, NULL, 0);
    else
        fw->alt_base = 0;

    // Max (old) sig size is 32, add extra space at end of buffer and fill with 0xFFFFFFFF
    // Allows sig matching past end of firmware without checking each time in the inner loop
    fw->buf = malloc((fw->size+32)*4);
    k = fread(fw->buf, 4, fw->size, f);
    fclose(f);

    // fill extra space in buffer
    memset(&fw->buf[fw->size],0xff,32*4);

    // Find all the valid ranges for checking (skips over large blocks of 0xFFFFFFFF)
    findRanges(fw);

    // Check for DIGIC 4+ dump
    // assumes dump starting with either the main firmware or the bootloader
    fw->main_offs = 0;
    if (os_type == OS_DRYOS)
    {
        k = find_str(fw, "gaonisoy");
        if (k != 1)
        {
            fw->main_offs = 0x10000 / 4;
        }
    }
    // Get DRYOS version
    fw->real_dryos_ver = fw->dryos_ver = 0;
    if (os_type == OS_DRYOS)
    {
        k = find_str(fw, "DRYOS version 2.3, release #");
        if (k != -1)
        {
            fw->real_dryos_ver = fw->dryos_ver = atoi(((char*)&fw->buf[k])+28);
            fw->dryos_ver_str = (char*)&fw->buf[k];
        }
    }

    // Get firmware version info
    fw->firmware_ver_str = 0;
    k = find_str(fw, "Firmware Ver ");
    if (os_type == OS_VXWORKS)
    {
        if (k < 0)
        {
            k = find_str(fw, "Firmware Version GM");    // ixus700
        }
        if (k < 0)
        {
            k = find_str(fw, "Firmware Version ");      // ixus30/40
        }
    }
    if (k != -1)
    {
        fw->firmware_ver_str = (char*)&fw->buf[k];
        fw->fwver_idx = k;
    }

    // Get camera name & platformid     ***** UPDATE for new each new DryOS version *****
    fw->fsize = -((int)fw->base)/4;
    if (fw->alt_base) fw->fsize = -((int)fw->alt_base)/4;
    fw->cam_idx = -1;
    fw->pid_adr = 0xffffffff;
    fw->cam = 0;
    fw->pid = 0;
    if (os_type == OS_DRYOS)
    {
        if (fw->dryos_ver > 59) fw->dryos_ver = 59; // UPDATE when support is added for higher DryOS versions
        switch (fw->dryos_ver)
        {
            case 20:
            case 23:
            case 31:
            case 39:
                fw->cam_idx = adr2idx(fw,0xFFFE0110);
                fw->pid_adr = 0xFFFE0130;
                break;
            case 43:
            case 45:
                fw->cam_idx = adr2idx(fw,0xFFFE00D0);
                fw->pid_adr = 0xFFFE0130;
                break;
            case 47:
                fw->cam_idx = adr2idx(fw,(fw->base==0xFF000000)?0xFFF40170:0xFFFE0170);
                fw->pid_adr = (fw->base==0xFF000000)?0xFFF40040:0xFFFE0040;
                break;
            case 49:
            case 50:
            case 51:
            case 52:
                if (fw->alt_base)
                {
                    fw->cam_idx = adr2idx(fw,(fw->alt_base==0xFF000000)?0xFFF40190:0xFFFE0170);
                    fw->pid_adr = (fw->alt_base==0xFF000000)?0xFFF40040:0xFFFE0040;
                    if (idx_valid(fw,fw->cam_idx) && (strncmp((char*)fwadr(fw,fw->cam_idx),"Canon ",6) != 0))
                        fw->cam_idx = adr2idx(fw,(fw->alt_base==0xFF000000)?0xFFF40170:0xFFFE0170);
                }
                else
                {
                    fw->cam_idx = adr2idx(fw,(fw->base==0xFF000000)?0xFFF40190:0xFFFE0170);
                    fw->pid_adr = (fw->base==0xFF000000)?0xFFF40040:0xFFFE0040;
                    if (idx_valid(fw,fw->cam_idx) && (strncmp((char*)fwadr(fw,fw->cam_idx),"Canon ",6) != 0))
                        fw->cam_idx = adr2idx(fw,(fw->base==0xFF000000)?0xFFF40170:0xFFFE0170);
                }
                break;
            case 54:
                fw->cam_idx = adr2idx(fw,(fw->base==0xFF010000)?0xFFF40170:0xFFFF0170);
                fw->pid_adr = (fw->base==0xFF010000)?0xFFF40040:0xFFFF0040;
                break;
            case 55:
            case 57: // TODO: based on a single fw dump (ixus275)
                fw->cam_idx = adr2idx(fw,(fw->base==0xFF010000)?0xFFFE0170:0xFFFF0170);
                fw->pid_adr = (fw->base==0xFF010000)?0xFFFE0040:0xFFFF0040;
                break;
            case 58:
            case 59:
                fw->cam_idx = adr2idx(fw,(fw->base==0xFF010000)?0xFFFE03A0:0xFFFF03A0);
                fw->pid_adr = (fw->base==0xFF010000)?0xFFFE0270:0xFFFF0270;
                break;
        }
    }
    else
    {
        //                             IXUS 700    IXUS 30/40  IXUS 50     Other
        uint32_t vx_name_offsets[] = { 0xFFD70110, 0xFFD70120, 0xFFF80110, 0xFFFE0110 };
        uint32_t vx_pid_offsets[] =  { 0xFFD70130, 0xFFD7014E, 0xFFF80130, 0xFFFE0130 };
        for (i=0; i<(int)(sizeof(vx_name_offsets)/sizeof(vx_name_offsets[0])); i++)
        {
            int k = adr2idx(fw,vx_name_offsets[i]);
            if (idx_valid(fw,k) && (strncmp((char*)fwadr(fw,k),"Canon ",6) == 0))
            {
                fw->cam_idx = k;
                fw->pid_adr = vx_pid_offsets[i];
                break;
            }
        }
    }

    // Extact camera name if found
    if (idx_valid(fw,fw->cam_idx) && (strncmp((char*)fwadr(fw,fw->cam_idx),"Canon ",6) == 0))
    {
        fw->cam = (char*)fwadr(fw,fw->cam_idx);
    }

    // Set ID if found
    if (idx_valid(fw,adr2idx(fw,fw->pid_adr)) && (fw->pid_adr != 0xffffffff))
    {
        // get the correct halfword
        fw->pid = (fwval(fw,adr2idx(fw,fw->pid_adr)) >> ((fw->pid_adr & 2)?16:0)) & 0xFFFF;
    }

    // Calc MAXRAMADDR
    fw->maxram = 0;
    if (os_type == OS_DRYOS)
    {
        if (((fw->buf[0x10 + fw->main_offs] & 0xFFFFFF00) == 0xE3A00000) && (fw->buf[0x11 + fw->main_offs] == 0xEE060F12))
        {
            fw->maxram = (1 << (((fw->buf[0x10 + fw->main_offs] & 0x3E) >> 1) + 1)) - 1;
        }
        else if (((fw->buf[0x14 + fw->main_offs] & 0xFFFFFF00) == 0xE3A00000) && (fw->buf[0x15 + fw->main_offs] == 0xEE060F12))
        {
            fw->maxram = (1 << (((fw->buf[0x14 + fw->main_offs] & 0x3E) >> 1) + 1)) - 1;
        }
    }
    else if (os_type == OS_VXWORKS)
    {
        for (k=16; k<100; k++)
        {
            if ((fw->buf[k] & 0xFFFF0FFF) == 0xEE060F12) // mcr 15, 0, rx, cr6, cr2, {0}
            {
                fw->maxram = (1 << (((fw->buf[k-1] & 0x3E) >> 1) + 1)) - 1;
                break;
            }
        }
    }

    // Find MEMISOSTART
    fw->memisostart = 0;
    if (os_type == OS_DRYOS)
    {
        for (k=0 + fw->main_offs; k<(100 + fw->main_offs); k++)
        {
            if (isLDR_PC(fw,k) && (LDR2val(fw,k) == 0x1900) && isLDR_PC(fw,k+6))
            {
                fw->memisostart = LDR2val(fw,k+6);
            }
        }
    }
    else if (os_type == OS_VXWORKS)
    {
        for (k=16; k<100; k++)
        {
            if (isMOV_immed(fw,k) && (ALUop2(fw,k) == 0x1900) && isLDR_PC(fw,k+11))
            {
                fw->memisostart = LDR2val(fw,k+11);
                // Find DATA section info
                if (isLDR_PC(fw,k-1) && isLDR_PC(fw,k-4) && ((fwval(fw,k-2) & 0xFFF0FFF0) == 0xE1500000))
                {
                    uint32_t fadr = LDR2val(fw,k-1);
                    uint32_t dadr = 0x1900;
                    uint32_t eadr = LDR2val(fw,k-4);
                    if ((fadr > fw->base) && (dadr < fw->base))
                    {
                        fw->data_start = dadr;
                        fw->data_init_start = fadr;
                        fw->data_len = eadr / 4;
                    }
                }
                break;
            }
            else if (isMOV_immed(fw,k) && (ALUop2(fw,k) == 0x1900) && isLDR_PC(fw,k-2) && isLDR_PC(fw,k-3))
            {
                // special case ixus30/40
                fw->maxram = 0x1FFFFFF; // 32MB, difficult to find
                fw->memisostart = 0x1900 + LDR2val(fw,k-3);
                // Find DATA section info
                fw->data_init_start = LDR2val(fw,k-2);
                fw->data_start = 0x1900;
                j = idxFollowBranch(fw, k+6, 1);
                if (j != k+6)
                {
                    k = idxFollowBranch(fw, j+1, 0x01000001);
                    if (k != j+1)
                    {
                        if ( isLDR_PC(fw,k+3) )
                        {
                            uint32_t eadr = LDR2val(fw,k+3);
                            if ( (eadr>0x1000) && (eadr< fw->memisostart - 0x1900) )
                            {
                                fw->data_len = (eadr - 0x1900) / 4;
                            }
                        }
                    }
                }
                break;
            }
            else if (isMOV_immed(fw,k) && (ALUop2(fw,k) == 0x1900) && isLDR_PC(fw,k-2) &&
                        ((fwval(fw,k-1) & 0xFFFF0F00) == 0xE50B0000) && isLDR_PC(fw,k+28) && isLDR_PC(fw,k+4)
                    )
            {
                // special case ixusW
                fw->memisostart = LDR2val(fw,k+28);
                // Find DATA section info
                fw->data_init_start = LDR2val(fw,k-2);
                fw->data_start = 0x1900;
                fw->data_len = (LDR2val(fw,k+4) - 0x1900) / 4;
                break;
            }
        }
    }

    // Find encryption key & dancing bits
    fw->ksys_idx = 0;
    fw->ksys = 0;
    fw->dancing_bits_idx = 0;
    fw->dancing_bits = 0;
    if (os_type == OS_DRYOS)
    {
        uint32_t ofst = (fw->main_offs)?0:adr2idx(fw,0xFFFF0000); // Offset of area to find dancing bits
        if (idx_valid(fw,ofst) && isB(fw,ofst) && isLDR_PC(fw,ofst+1))
        {
            // Get KEYSYS value
            ofst = adr2idx(fw,LDR2val(fw,ofst+1));     // Address of firmware encryption key
            if (idx_valid(fw,ofst))
            {
                fw->ksys_idx = ofst;
                fw->ksys = "? Not found, possible new firmware encryption key.";
                switch (fwval(fw,ofst))
                {
                    // Note: only check first word of key (assumes Canon won't release a new key with the same initial value as an existing one)
                    // (Avoid storing full encryption key in this source code).
                    case 0x70726964:    fw->ksys = "d3"; break;
                    case 0x646C726F:    fw->ksys = "d3enc"; break;
                    case 0x774D450B:    fw->ksys = "d4"; break;
                    case 0x80751A95:    fw->ksys = "d4a"; break;
                    case 0x76894368:    fw->ksys = "d4b"; break;
                    case 0x50838EF7:    fw->ksys = "d4c"; break;
                    case 0xCCE4D2E6:    fw->ksys = "d4d"; break;
                    case 0x66E0C6D2:    fw->ksys = "d4e"; break;
                    case 0xE1268DB4:    fw->ksys = "d4f"; break;
                    case 0x216EA8C8:    fw->ksys = "d4g"; break;
                    case 0x45264974:    fw->ksys = "d4h"; break;
                    case 0x666363FC:    fw->ksys = "d4i"; break;
                    case 0xAE8DB5AF:    fw->ksys = "d4j"; break;
                }
            }

            // Get NEED_ENCODED_DISKBOOT value
            ofst = ofst + 4; // Address of dancing bits data (try after firmware key)
            if (idx_valid(fw,ofst))
            {
                for (i=0; i<VITALY && !fw->dancing_bits; i++)
                {
                    fw->dancing_bits = i+1;
                    for (j=0; j<8 && fw->dancing_bits; j++)
                    {
                        if ((fwval(fw,ofst+j) & 0xFF) != _chr_[i][j])
                        {
                            fw->dancing_bits = 0;
                        }
                    }
                }
                if (!fw->dancing_bits)
                {
                    // Try before firmware key
                    ofst = ofst - 12;
                    for (i=0; i<VITALY && !fw->dancing_bits; i++)
                    {
                        fw->dancing_bits = i+1;
                        for (j=0; j<8 && fw->dancing_bits; j++)
                        {
                            if ((fwval(fw,ofst+j) & 0xFF) != _chr_[i][j])
                            {
                                fw->dancing_bits = 0;
                            }
                        }
                    }
                }
                if (fw->dancing_bits != 0)
                {
                    // Make sure LoadBootFile actually fails on files that are not encoded
                    // E.G. G9 - will load and run an un-encoded DISKBOOT.BIN file
                    int need_dance = 1;
                    for (k = ofst; (k>adr2idx(fw,0xFFFF0000)) && need_dance; k--)
                    {
                        if (isLDR_PC(fw,k) && (LDR2val(fw,k) == idx2adr(fw,ofst)))
                        {
                            j = find_inst_rev(fw,isSTMFD_LR,k-1,10);
                            if (j >= 0)
                            {
                                uint32_t fadr = idx2adr(fw,j);
                                for (i=j-200; i<j+200 && need_dance; i++)
                                {
                                    if (isB(fw,i))
                                    {
                                        uint32_t badr = followBranch(fw,idx2adr(fw,i),1);
                                        if (badr == fadr)
                                        {
                                            int l;
                                            for (l=i-1; l>i-50; l--)
                                            {
                                                if (isLDR(fw,l) && isCMP(fw,l+1) && isBX_cond(fw,l+2))
                                                {
                                                    need_dance = 0;
                                                    break;
                                                }
                                            }
                                        }
                                    }
                                }
                            }
                        }
                    }
                    if (need_dance)
                        fw->dancing_bits_idx = ofst;
                    else
                        fw->dancing_bits = 0;
                }
            }
        }
    }

    int dx = 3;

    fw->lowest_idx = 0;

    // DryOS R50/R51/R52 etc. copies a block of ROM to RAM and then uses that copy
    // Need to allow for this in finding addresses
    // Seen on SX260HS
    if (fw->dryos_ver >= 50)
    {

        // Try and find ROM address copied, and location copied to
        for (i=3 + fw->main_offs; i<(100 + fw->main_offs); i++)
        {
            if (isLDR_PC(fw,i) && isLDR_PC(fw,i+1) && (isLDR_PC(fw,i+2)))
            {
                uint32_t fadr = LDR2val(fw,i);
                uint32_t dadr = LDR2val(fw,i+1);
                uint32_t eadr = LDR2val(fw,i+2);
                if ((fadr > fw->base) && (dadr < fw->base))
                {
                    fw->buf2 = &fw->buf[adr2idx(fw,fadr)];
                    fw->base2 = dadr;
                    fw->base_copied = fadr;
                    fw->size2 = (eadr - dadr) / 4;
                    fw->lowest_idx = adr2idx(fw,fw->base2);
                    dx = i+3;
                    break;
                }
            }
        }
    }

    // Find DATA section info
    if (os_type == OS_DRYOS)
    {
        for (i=dx; i<(100 + fw->main_offs); i++)
        {
            if (isLDR_PC(fw,i) && isLDR_PC(fw,i+1) && (isLDR_PC(fw,i+2)))
            {
                uint32_t fadr = LDR2val(fw,i);
                uint32_t dadr = LDR2val(fw,i+1);
                uint32_t eadr = LDR2val(fw,i+2);
                if ((fadr > fw->base) && (dadr < fw->base))
                {
                    fw->data_start = dadr;
                    fw->data_init_start = fadr;
                    fw->data_len = (eadr - dadr) / 4;
                    break;
                }
            }
        }
    }
}

int search_fw	(	firmware *	fw,
		int(*)(firmware *, int, uint32_t, uint32_t)	func,
		uint32_t	v1,
		uint32_t	v2,
		int	len
	)

Definiert in Zeile 881 der Datei firmware_load.c.

{
    BufRange *p = fw->br;
    while (p)
    {
        int k;
        for (k = p->off; k <= p->off + p->len - len; k++)
        {
            int rv = func(fw,k,v1,v2);
            if (rv != 0)
                return rv;
        }
        p = p->next;
    }
    return 0;
}

int search_fw_bytes	(	firmware *	fw,
		int(*)(firmware *, int)	func
	)

Definiert in Zeile 903 der Datei firmware_load.c.

{
    BufRange *p = fw->br;
    while (p)
    {
        int k;
        for (k = p->off*4; k < (p->off + p->len)*4; k++)
        {
            if (func(fw,k))
                return 1;
        }
        p = p->next;
    }
    return 0;
}

void set_ignore_errors

(

int

n)

Definiert in Zeile 212 der Datei firmware_load.c.

{
    ignore_errors = n;
}

void usage

(

char *

err)

Definiert in Zeile 1103 der Datei code_gen.c.

{
    fprintf(stderr,"code_gen <base> <primary> [alt base] - Error = %s\n",err);
    exit(1);
}

Variablen-Dokumentation

int ignore_errors = 0

static

Definiert in Zeile 210 der Datei firmware_load.c.