FreeCalypso > hg > freecalypso-tools
view target-utils/loadagent/amdflash.c @ 1014:961efadd530a default tip
fc-shell TCH DL handler: add support for CSD modes
TCH DL capture mechanism in FC Tourmaline firmware has been extended
to support CSD modes in addition to speech - add the necessary support
on the host tools side.
It needs to be noted that this mechanism in its present state does NOT
provide the debug utility value that was sought: as we learned only
after the code was implemented, TI's DSP has a misfeature in that the
buffer we are reading (a_dd_0[]) is zeroed out when the IDS block
is enabled, i.e., we are reading all zeros and not the real DL bits
we were after. But since the code has already been written, we are
keeping it - perhaps we can do some tests with IDS disabled.
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Tue, 26 Nov 2024 06:27:43 +0000 |
| parents | b34384991094 |
| children |
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/* * This module implements the AMFB and AMFW commands for programming * AMD-style flash memories. Syntax: * * AMFB <baseaddr> -- sets the base address for subsequent AMFW commands * AMFW <offset> <hexstring> -- the actual flash write operation * * The flash memory is assumed to be 16 bits wide. The hex string * argument to the AMFW command is just data, with no header, address, * length, checksum or other additions. The number of hex digits in the * string must be a multiple of 4, and the byte order is the same as * that of TI's *.m0 files: we interpret the string as consisting of * 16-bit words rather than bytes. * * The address to which each flash write is directed is the sum of the * base given to AMFB and the offset given to AMFW. The fixed offsets * of 0xAAA and 0x554 (0x555 and 0x2AA in words) prescribed for the flash * programming command sequence are also made from the base set with AMFB. */ #include <sys/types.h> #include "types.h" static u32 base_addr; void cmd_AMFB(argbulk) char *argbulk; { char *argv[2]; u_long addr; if (parse_args(argbulk, 1, 1, argv, 0) < 0) return; if (parse_hexarg(argv[0], 8, &addr) < 0) { printf("ERROR: argument must be a valid 32-bit hex address\n"); return; } if (addr & 1) { printf("ERROR: odd address\n"); return; } base_addr = addr; } void cmd_AMFW(argbulk) char *argbulk; { char *argv[3], *s; u_long offset; volatile u16 *flashptr; u32 datum; /* needs to be u32 for decode_hex_digits() */ int i; if (parse_args(argbulk, 2, 2, argv, 0) < 0) return; if (parse_hexarg(argv[0], 8, &offset) < 0) { printf("ERROR: offset argument must a valid 32-bit hex value\n"); return; } if (offset & 1) { printf("ERROR: odd offset argument\n"); return; } flashptr = (volatile u16 *)(base_addr + offset); for (s = argv[1]; *s; flashptr++, s += 4) { if (decode_hex_digits(s, 4, &datum) < 0) { printf("ERROR: bad AMFW hex string argument\n"); return; } if (*flashptr != 0xFFFF) { printf("ERROR: flash not blank at %08X\n", (u_long) flashptr); return; } *(volatile u16 *)(base_addr + 0xAAA) = 0xAA; *(volatile u16 *)(base_addr + 0x554) = 0x55; *(volatile u16 *)(base_addr + 0xAAA) = 0xA0; *flashptr = datum; for (i = 10000; i; i--) if (*flashptr == datum) break; if (!i) { printf("ERROR: flash write timeout at %08X\n", (u_long) flashptr); return; } } } amdflash_binary_prog(offset, nwords, data) u32 offset; unsigned nwords; u16 *data; { volatile u16 *flashptr; int i; flashptr = (volatile u16 *)(base_addr + offset); while (nwords) { if (*flashptr != 0xFFFF) { serial_out(0x15); /* NAK */ printf("ERROR: flash not blank at %08X\n", (u_long) flashptr); return(-1); } *(volatile u16 *)(base_addr + 0xAAA) = 0xAA; *(volatile u16 *)(base_addr + 0x554) = 0x55; *(volatile u16 *)(base_addr + 0xAAA) = 0xA0; *flashptr = *data; for (i = 10000; i; i--) if (*flashptr == *data) break; if (!i) { serial_out(0x15); /* NAK */ printf("ERROR: flash write timeout at %08X\n", (u_long) flashptr); return(-1); } flashptr++; data++; nwords--; } return(0); } void cmd_AMFWB() { binary_flash_prog_main(amdflash_binary_prog); }