Change section_start pointer to char** to prevent aliasing warnings on old toolchain

[proxmark3-svn] / armsrc / fpgaloader.c

//-----------------------------------------------------------------------------\r
// Routines to load the FPGA image, and then to configure the FPGA's major\r
// mode once it is configured.\r
//\r
// Jonathan Westhues, April 2006\r
//-----------------------------------------------------------------------------\r
#include <proxmark3.h>\r
#include "apps.h"\r
\r
//-----------------------------------------------------------------------------\r
// Set up the Serial Peripheral Interface as master\r
// Used to write the FPGA config word\r
// May also be used to write to other SPI attached devices like an LCD\r
//-----------------------------------------------------------------------------\r
void SetupSpi(int mode)\r
{\r
	// PA10 -> SPI_NCS2 chip select (LCD)\r
	// PA11 -> SPI_NCS0 chip select (FPGA)\r
	// PA12 -> SPI_MISO Master-In Slave-Out\r
	// PA13 -> SPI_MOSI Master-Out Slave-In\r
	// PA14 -> SPI_SPCK Serial Clock\r
\r
	// Disable PIO control of the following pins, allows use by the SPI peripheral\r
	PIO_DISABLE			 =	(1 << GPIO_NCS0)	|\r
							(1 << GPIO_NCS2) 	|\r
							(1 << GPIO_MISO)	|\r
							(1 << GPIO_MOSI)	|\r
							(1 << GPIO_SPCK);\r
\r
	PIO_PERIPHERAL_A_SEL =	(1 << GPIO_NCS0)	|\r
							(1 << GPIO_MISO)	|\r
							(1 << GPIO_MOSI)	|\r
							(1 << GPIO_SPCK);\r
\r
	PIO_PERIPHERAL_B_SEL =	(1 << GPIO_NCS2);\r
\r
	//enable the SPI Peripheral clock\r
	PMC_PERIPHERAL_CLK_ENABLE = (1<<PERIPH_SPI);\r
	// Enable SPI\r
	SPI_CONTROL = SPI_CONTROL_ENABLE;\r
\r
	switch (mode) {\r
		case SPI_FPGA_MODE:\r
			SPI_MODE =\r
				( 0 << 24)	|	// Delay between chip selects (take default: 6 MCK periods)\r
				(14 << 16)	|	// Peripheral Chip Select (selects FPGA SPI_NCS0 or PA11)\r
				( 0 << 7)	|	// Local Loopback Disabled\r
				( 1 << 4)	|	// Mode Fault Detection disabled\r
				( 0 << 2)	|	// Chip selects connected directly to peripheral\r
				( 0 << 1) 	|	// Fixed Peripheral Select\r
				( 1 << 0);		// Master Mode\r
			SPI_FOR_CHIPSEL_0 =\r
				( 1 << 24)	|	// Delay between Consecutive Transfers (32 MCK periods)\r
				( 1 << 16)	|	// Delay Before SPCK (1 MCK period)\r
				( 6 << 8)	|	// Serial Clock Baud Rate (baudrate = MCK/6 = 24Mhz/6 = 4M baud\r
				( 8 << 4)	|	// Bits per Transfer (16 bits)\r
				( 0 << 3)	|	// Chip Select inactive after transfer\r
				( 1 << 1)	|	// Clock Phase data captured on leading edge, changes on following edge\r
				( 0 << 0);		// Clock Polarity inactive state is logic 0\r
			break;\r
		case SPI_LCD_MODE:\r
			SPI_MODE =\r
				( 0 << 24)	|	// Delay between chip selects (take default: 6 MCK periods)\r
				(11 << 16)	|	// Peripheral Chip Select (selects LCD SPI_NCS2 or PA10)\r
				( 0 << 7)	|	// Local Loopback Disabled\r
				( 1 << 4)	|	// Mode Fault Detection disabled\r
				( 0 << 2)	|	// Chip selects connected directly to peripheral\r
				( 0 << 1) 	|	// Fixed Peripheral Select\r
				( 1 << 0);		// Master Mode\r
			SPI_FOR_CHIPSEL_2 =\r
				( 1 << 24)	|	// Delay between Consecutive Transfers (32 MCK periods)\r
				( 1 << 16)	|	// Delay Before SPCK (1 MCK period)\r
				( 6 << 8)	|	// Serial Clock Baud Rate (baudrate = MCK/6 = 24Mhz/6 = 4M baud\r
				( 1 << 4)	|	// Bits per Transfer (9 bits)\r
				( 0 << 3)	|	// Chip Select inactive after transfer\r
				( 1 << 1)	|	// Clock Phase data captured on leading edge, changes on following edge\r
				( 0 << 0);		// Clock Polarity inactive state is logic 0\r
			break;\r
		default:				// Disable SPI\r
			SPI_CONTROL = SPI_CONTROL_DISABLE;\r
			break;\r
	}\r
}\r
\r
//-----------------------------------------------------------------------------\r
// Set up the synchronous serial port, with the one set of options that we\r
// always use when we are talking to the FPGA. Both RX and TX are enabled.\r
//-----------------------------------------------------------------------------\r
void FpgaSetupSsc(void)\r
{\r
	// First configure the GPIOs, and get ourselves a clock.\r
	PIO_PERIPHERAL_A_SEL =	(1 << GPIO_SSC_FRAME)	|\r
							(1 << GPIO_SSC_DIN)		|\r
							(1 << GPIO_SSC_DOUT)	|\r
							(1 << GPIO_SSC_CLK);\r
	PIO_DISABLE = (1 << GPIO_SSC_DOUT);\r
\r
	PMC_PERIPHERAL_CLK_ENABLE = (1 << PERIPH_SSC);\r
\r
	// Now set up the SSC proper, starting from a known state.\r
	SSC_CONTROL = SSC_CONTROL_RESET;\r
\r
	// RX clock comes from TX clock, RX starts when TX starts, data changes\r
	// on RX clock rising edge, sampled on falling edge\r
	SSC_RECEIVE_CLOCK_MODE = SSC_CLOCK_MODE_SELECT(1) | SSC_CLOCK_MODE_START(1);\r
\r
	// 8 bits per transfer, no loopback, MSB first, 1 transfer per sync\r
	// pulse, no output sync, start on positive-going edge of sync\r
	SSC_RECEIVE_FRAME_MODE = SSC_FRAME_MODE_BITS_IN_WORD(8) |\r
		SSC_FRAME_MODE_MSB_FIRST | SSC_FRAME_MODE_WORDS_PER_TRANSFER(0);\r
\r
	// clock comes from TK pin, no clock output, outputs change on falling\r
	// edge of TK, start on rising edge of TF\r
	SSC_TRANSMIT_CLOCK_MODE = SSC_CLOCK_MODE_SELECT(2) |\r
		SSC_CLOCK_MODE_START(5);\r
\r
	// tx framing is the same as the rx framing\r
	SSC_TRANSMIT_FRAME_MODE = SSC_RECEIVE_FRAME_MODE;\r
\r
	SSC_CONTROL = SSC_CONTROL_RX_ENABLE | SSC_CONTROL_TX_ENABLE;\r
}\r
\r
//-----------------------------------------------------------------------------\r
// Set up DMA to receive samples from the FPGA. We will use the PDC, with\r
// a single buffer as a circular buffer (so that we just chain back to\r
// ourselves, not to another buffer). The stuff to manipulate those buffers\r
// is in apps.h, because it should be inlined, for speed.\r
//-----------------------------------------------------------------------------\r
void FpgaSetupSscDma(BYTE *buf, int len)\r
{\r
	PDC_RX_POINTER(SSC_BASE) = (DWORD)buf;\r
	PDC_RX_COUNTER(SSC_BASE) = len;\r
	PDC_RX_NEXT_POINTER(SSC_BASE) = (DWORD)buf;\r
	PDC_RX_NEXT_COUNTER(SSC_BASE) = len;\r
	PDC_CONTROL(SSC_BASE) = PDC_RX_ENABLE;\r
}\r
\r
static void DownloadFPGA_byte(unsigned char w)\r
{\r
#define SEND_BIT(x) { if(w & (1<<x) ) HIGH(GPIO_FPGA_DIN); else LOW(GPIO_FPGA_DIN); HIGH(GPIO_FPGA_CCLK); LOW(GPIO_FPGA_CCLK); }\r
	SEND_BIT(7);\r
	SEND_BIT(6);\r
	SEND_BIT(5);\r
	SEND_BIT(4);\r
	SEND_BIT(3);\r
	SEND_BIT(2);\r
	SEND_BIT(1);\r
	SEND_BIT(0);\r
}\r
\r
// Download the fpga image starting at FpgaImage and with length FpgaImageLen bytes\r
// If bytereversal is set: reverse the byte order in each 4-byte word\r
static void DownloadFPGA(const char *FpgaImage, int FpgaImageLen, int bytereversal)\r
{\r
	int i;\r
\r
	PIO_OUTPUT_ENABLE = (1 << GPIO_FPGA_ON);\r
	PIO_ENABLE = (1 << GPIO_FPGA_ON);\r
	PIO_OUTPUT_DATA_SET = (1 << GPIO_FPGA_ON);\r
\r
	SpinDelay(50);\r
\r
	LED_D_ON();\r
\r
	HIGH(GPIO_FPGA_NPROGRAM);\r
	LOW(GPIO_FPGA_CCLK);\r
	LOW(GPIO_FPGA_DIN);\r
	PIO_OUTPUT_ENABLE = (1 << GPIO_FPGA_NPROGRAM)	|\r
						(1 << GPIO_FPGA_CCLK)		|\r
						(1 << GPIO_FPGA_DIN);\r
	SpinDelay(1);\r
\r
	LOW(GPIO_FPGA_NPROGRAM);\r
	SpinDelay(50);\r
	HIGH(GPIO_FPGA_NPROGRAM);\r
\r
	if(bytereversal) {\r
		/* This is only supported for DWORD aligned images */\r
		if( ((int)FpgaImage % sizeof(DWORD)) == 0 ) {\r
			i=0;\r
			while(FpgaImageLen-->0)\r
				DownloadFPGA_byte(FpgaImage[(i++)^0x3]);\r
			/* Explanation of the magic in the above line: \r
			 * i^0x3 inverts the lower two bits of the integer i, counting backwards\r
			 * for each 4 byte increment. The generated sequence of (i++)^3 is\r
			 * 3 2 1 0 7 6 5 4 11 10 9 8 15 14 13 12 etc. pp. 
			 */\r
		}\r
	} else {\r
		while(FpgaImageLen-->0)\r
			DownloadFPGA_byte(*FpgaImage++);\r
	}\r
\r
	LED_D_OFF();\r
}\r
\r
static char *bitparse_headers_start;\r
static char *bitparse_bitstream_end;\r
static int bitparse_initialized;\r
/* Simple Xilinx .bit parser. The file starts with the fixed opaque byte sequence\r
 * 00 09 0f f0 0f f0 0f f0 0f f0 00 00 01\r
 * After that the format is 1 byte section type (ASCII character), 2 byte length\r
 * (big endian), <length> bytes content. Except for section 'e' which has 4 bytes\r
 * length.
 */\r
static const char _bitparse_fixed_header[] = {0x00, 0x09, 0x0f, 0xf0, 0x0f, 0xf0, 0x0f, 0xf0, 0x0f, 0xf0, 0x00, 0x00, 0x01};\r
static int bitparse_init(void * start_address, void *end_address)\r
{\r
	bitparse_initialized = 0;\r
	\r
	if(memcmp(_bitparse_fixed_header, start_address, sizeof(_bitparse_fixed_header)) != 0) {\r
		return 0; /* Not matched */\r
	} else {\r
		bitparse_headers_start= ((char*)start_address) + sizeof(_bitparse_fixed_header);\r
		bitparse_bitstream_end= (char*)end_address;\r
		bitparse_initialized = 1;\r
		return 1;\r
	}\r
}\r
\r
int bitparse_find_section(char section_name, char **section_start, unsigned int *section_length)\r
{\r
	char *pos = bitparse_headers_start;\r
	int result = 0;\r
\r
	if(!bitparse_initialized) return 0;\r
\r
	while(pos < bitparse_bitstream_end) {\r
		char current_name = *pos++;\r
		unsigned int current_length = 0;\r
		if(current_name < 'a' || current_name > 'e') {\r
			/* Strange section name, abort */\r
			break;\r
		}\r
		current_length = 0;\r
		switch(current_name) {\r
		case 'e':\r
			/* Four byte length field */\r
			current_length += (*pos++) << 24;\r
			current_length += (*pos++) << 16;\r
		default: /* Fall through, two byte length field */\r
			current_length += (*pos++) << 8;\r
			current_length += (*pos++) << 0;\r
		}\r
		\r
		if(current_name != 'e' && current_length > 255) {\r
			/* Maybe a parse error */\r
			break;\r
		}\r
		\r
		if(current_name == section_name) {\r
			/* Found it */\r
			*section_start = pos;\r
			*section_length = current_length;\r
			result = 1;\r
			break;\r
		}\r
		\r
		pos += current_length; /* Skip section */\r
	}\r
	\r
	return result;\r
}\r
\r
//-----------------------------------------------------------------------------\r
// Find out which FPGA image format is stored in flash, then call DownloadFPGA\r
// with the right parameters to download the image\r
//-----------------------------------------------------------------------------\r
extern char _binary_fpga_bit_start, _binary_fpga_bit_end;\r
void FpgaDownloadAndGo(void)\r
{\r
	/* Check for the new flash image format: Should have the .bit file at &_binary_fpga_bit_start
	 */\r
	if(bitparse_init(&_binary_fpga_bit_start, &_binary_fpga_bit_end)) {\r
		/* Successfully initialized the .bit parser. Find the 'e' section and\r
		 * send its contents to the FPGA.
		 */\r
		char *bitstream_start;\r
		unsigned int bitstream_length;\r
		if(bitparse_find_section('e', &bitstream_start, &bitstream_length)) {\r
			DownloadFPGA(bitstream_start, bitstream_length, 0);\r
			\r
			return; /* All done */\r
		}\r
	}\r
	\r
	/* Fallback for the old flash image format: Check for the magic marker 0xFFFFFFFF\r
	 * 0xAA995566 at address 0x102000. This is raw bitstream with a size of 336,768 bits \r
	 * = 10,524 DWORDs, stored as DWORDS e.g. little-endian in memory, but each DWORD\r
	 * is still to be transmitted in MSBit first order. Set the invert flag to indicate\r
	 * that the DownloadFPGA function should invert every 4 byte sequence when doing\r
	 * the bytewise download.
	 */\r
	if( *(DWORD*)0x102000 == 0xFFFFFFFF && *(DWORD*)0x102004 == 0xAA995566 )\r
		DownloadFPGA((char*)0x102000, 10524*4, 1);\r
}\r
\r
void FpgaGatherVersion(char *dst, int len)\r
{\r
	char *fpga_info; \r
	unsigned int fpga_info_len;\r
	dst[0] = 0;\r
	if(!bitparse_find_section('e', &fpga_info, &fpga_info_len)) {\r
		strncat(dst, "FPGA image: legacy image without version information", len-1);\r
	} else {\r
		strncat(dst, "FPGA image built", len-1);\r
		/* USB packets only have 48 bytes data payload, so be terse */\r
#if 0\r
		if(bitparse_find_section('a', &fpga_info, &fpga_info_len) && fpga_info[fpga_info_len-1] == 0 ) {\r
			strncat(dst, " from ", len-1);\r
			strncat(dst, fpga_info, len-1);\r
		}\r
		if(bitparse_find_section('b', &fpga_info, &fpga_info_len) && fpga_info[fpga_info_len-1] == 0 ) {\r
			strncat(dst, " for ", len-1);\r
			strncat(dst, fpga_info, len-1);\r
		}\r
#endif\r
		if(bitparse_find_section('c', &fpga_info, &fpga_info_len) && fpga_info[fpga_info_len-1] == 0 ) {\r
			strncat(dst, " on ", len-1);\r
			strncat(dst, fpga_info, len-1);\r
		}\r
		if(bitparse_find_section('d', &fpga_info, &fpga_info_len) && fpga_info[fpga_info_len-1] == 0 ) {\r
			strncat(dst, " at ", len-1);\r
			strncat(dst, fpga_info, len-1);\r
		}\r
	}\r
}\r
\r
//-----------------------------------------------------------------------------\r
// Send a 16 bit command/data pair to the FPGA.\r
// The bit format is:  C3 C2 C1 C0 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0\r
// where C is the 4 bit command and D is the 12 bit data\r
//-----------------------------------------------------------------------------\r
void FpgaSendCommand(WORD cmd, WORD v)\r
{\r
	SetupSpi(SPI_FPGA_MODE);\r
	while ((SPI_STATUS & SPI_STATUS_TX_EMPTY) == 0);		// wait for the transfer to complete\r
	SPI_TX_DATA = SPI_CONTROL_LAST_TRANSFER | cmd | v;		// send the data\r
}\r
//-----------------------------------------------------------------------------\r
// Write the FPGA setup word (that determines what mode the logic is in, read\r
// vs. clone vs. etc.). This is now a special case of FpgaSendCommand() to\r
// avoid changing this function's occurence everywhere in the source code.\r
//-----------------------------------------------------------------------------\r
void FpgaWriteConfWord(BYTE v)\r
{\r
	FpgaSendCommand(FPGA_CMD_SET_CONFREG, v);\r
}\r
\r
//-----------------------------------------------------------------------------\r
// Set up the CMOS switches that mux the ADC: four switches, independently\r
// closable, but should only close one at a time. Not an FPGA thing, but\r
// the samples from the ADC always flow through the FPGA.\r
//-----------------------------------------------------------------------------\r
void SetAdcMuxFor(int whichGpio)\r
{\r
	PIO_OUTPUT_ENABLE = (1 << GPIO_MUXSEL_HIPKD) |\r
						(1 << GPIO_MUXSEL_LOPKD) |\r
						(1 << GPIO_MUXSEL_LORAW) |\r
						(1 << GPIO_MUXSEL_HIRAW);\r
\r
	PIO_ENABLE		=	(1 << GPIO_MUXSEL_HIPKD) |\r
						(1 << GPIO_MUXSEL_LOPKD) |\r
						(1 << GPIO_MUXSEL_LORAW) |\r
						(1 << GPIO_MUXSEL_HIRAW);\r
\r
	LOW(GPIO_MUXSEL_HIPKD);\r
	LOW(GPIO_MUXSEL_HIRAW);\r
	LOW(GPIO_MUXSEL_LORAW);\r
	LOW(GPIO_MUXSEL_LOPKD);\r
\r
	HIGH(whichGpio);\r
}\r