collapseos/parts/z80/sdc.asm

; sdc
;
; Manages the initialization of a SD card and implement a block device to read
; and write from/to it, in SPI mode.
;
; Note that SPI can't really be used directly from the z80, so this part
; assumes that you have a device that handles SPI communication on behalf of
; the z80. This device is assumed to work in a particular way.
;
; That device has 3 ports. One write-only port to make CS high, one to make CS
; low (data sent is irrelevant), and one read/write port to send and receive
; bytes with the card through the SPI protocol. The device acts as a SPI master
; and writing to that port initiates a byte exchange. Data from the slave is
; then placed on a buffer that can be read by reading the same port.
;
; It's through that kind of device that this code below is supposed to work.

; *** Defines ***
; SDC_PORT_CSHIGH: Port number to make CS high
; SDC_PORT_CSLOW: Port number to make CS low
; SDC_PORT_SPI: Port number to send/receive SPI data

; Wake the SD card up. After power up, a SD card has to receive at least 74
; dummy clocks with CS and DI high. We send 80.
sdcWakeUp:
	out	(SDC_PORT_CSHIGH), a
	ld	b, 10		; 10 * 8 == 80
	ld	a, 0xff
.loop:
	out	(SDC_PORT_SPI), a
	nop
	djnz	.loop
	ret

; Initiate SPI exchange with the SD card. A is the data to send. Received data
; is placed in A.
sdcSendRecv:
	out	(SDC_PORT_SPI), a
	nop
	nop
	in	a, (SDC_PORT_SPI)
	nop
	nop
	ret

; sdcSendRecv 0xff until the response is something else than 0xff for a maximum
; of 20 times. Returns 0xff if no response.
sdcWaitResp:
	push	bc
	ld	b, 20
.loop:
	ld	a, 0xff
	call	sdcSendRecv
	inc	a		; if 0xff, it's going to become zero
	jr	nz, .end	; not zero? good, that's our command
	djnz	.loop
.end:
	; whether we had a success or failure, we return the result.
	; But first, let's bring it back to its original value.
	dec	a
	pop	bc
	ret

; Sends a command to the SD card, along with arguments and specified CRC fields.
; (CRC is only needed in initial commands though).
; A: Command to send
; H: Arg 1 (MSB)
; L: Arg 2
; D: Arg 3
; E: Arg 4 (LSB)
; C: CRC
;
; Returns R1 response in A.
;
; This does *not* handle CS. You have to select/deselect the card outside this
; routine.
sdcCmd:
	; Wait until ready to receive commands
	push	af
	call	sdcWaitResp
	pop	af

	call	sdcSendRecv
	; Arguments
	ld	a, h
	call	sdcSendRecv
	ld	a, l
	call	sdcSendRecv
	ld	a, d
	call	sdcSendRecv
	ld	a, e
	call	sdcSendRecv
	; send CRC
	ld	a, c
	call	sdcSendRecv

	; And now we just have to wait for a valid response...
	call	sdcWaitResp
	ret

; Send a command that expects a R1 response, handling CS.
sdcCmdR1:
	out	(SDC_PORT_CSLOW), a
	call	sdcCmd
	out	(SDC_PORT_CSHIGH), a
	ret

; Send a command that expects a R7 response, handling CS. A R7 is a R1 followed
; by 4 bytes. Those 4 bytes are returned in HL/DE in the same order as in
; sdcCmd.
sdcCmdR7:
	out	(SDC_PORT_CSLOW), a
	call	sdcCmd

	; We have our R1 response in A. Let's try reading the next 4 bytes in
	; case we have a R3.
	push	af
	ld	a, 0xff
	call	sdcSendRecv
	ld	h, a
	ld	a, 0xff
	call	sdcSendRecv
	ld	l, a
	ld	a, 0xff
	call	sdcSendRecv
	ld	d, a
	ld	a, 0xff
	call	sdcSendRecv
	ld	e, a
	pop	af

	out	(SDC_PORT_CSHIGH), a
	ret

; Initialize a SD card. This should be called at least 1ms after the powering
; up of the card. Sets result code in A. Zero means success, non-zero means
; error.
sdcInitialize:
	push	hl
	push	de
	push	bc
	call	sdcWakeUp

	; Call CMD0 and expect a 0x01 response (card idle)
	; This should be called multiple times. We're actually expected to.
	; Let's call this for a maximum of 10 times.
	ld	b, 10
.loop1:
	ld	a, 0b01000000	; CMD0
	ld	hl, 0
	ld	de, 0
	ld	c, 0x95
	call	sdcCmdR1
	cp	0x01
	jp	z, .cmd0ok
	djnz	.loop1
	; Nothing? error
	jr	.error
.cmd0ok:

	; Then comes the CMD8. We send it with a 0x01aa argument and expect
	; a 0x01aa argument back, along with a 0x01 R1 response.
	ld	a, 0b01001000	; CMD8
	ld	hl, 0
	ld	de, 0x01aa
	ld	c, 0x87
	call	sdcCmdR7
	cp	0x01
	jr	nz, .error
	xor	a
	cp	h	; H is zero
	jr	nz, .error
	cp	l	; L is zero
	jr	nz, .error
	ld	a, d
	cp	0x01
	jp	nz, .error
	ld	a, e
	cp	0xaa
	jr	nz, .error

	; Now we need to repeatedly run CMD55+CMD41 (0x40000000) until we
	; the card goes out of idle mode, that is, when it stops sending us
	; 0x01 response and send us 0x00 instead. Any other response means that
	; initialization failed.
.loop2:
	ld	a, 0b01110111	; CMD55
	ld	hl, 0
	ld	de, 0
	call	sdcCmdR1
	cp	0x01
	jr	nz, .error
	ld	a, 0b01101001	; CMD41 (0x40000000)
	ld	hl, 0x4000
	ld	de, 0x0000
	call	sdcCmdR1
	cp	0x01
	jr	z, .loop2
	or	a		; cp 0
	jr	nz, .error
	; Success! out of idle mode!
	; At this point, you are ready to read and write data.
	jr	.success

.error:
	ld	a, 0x01
	jr	.end

.success:
	xor	a
.end:
	pop	bc
	pop	de
	pop	hl
	ret
parts/z80/sdc: new part Incomplete, but what it does does work. I could handshake CMD0+CMD8 on a MicroSD HC. 2019-05-08 04:50:24 +10:00			`; sdc`
			`;`
			`; Manages the initialization of a SD card and implement a block device to read`
			`; and write from/to it, in SPI mode.`
			`;`
			`; Note that SPI can't really be used directly from the z80, so this part`
			`; assumes that you have a device that handles SPI communication on behalf of`
			`; the z80. This device is assumed to work in a particular way.`
			`;`
			`; That device has 3 ports. One write-only port to make CS high, one to make CS`
			`; low (data sent is irrelevant), and one read/write port to send and receive`
			`; bytes with the card through the SPI protocol. The device acts as a SPI master`
			`; and writing to that port initiates a byte exchange. Data from the slave is`
			`; then placed on a buffer that can be read by reading the same port.`
			`;`
			`; It's through that kind of device that this code below is supposed to work.`

			`; * Defines *`
			`; SDC_PORT_CSHIGH: Port number to make CS high`
			`; SDC_PORT_CSLOW: Port number to make CS low`
			`; SDC_PORT_SPI: Port number to send/receive SPI data`

			`; Wake the SD card up. After power up, a SD card has to receive at least 74`
			`; dummy clocks with CS and DI high. We send 80.`
			`sdcWakeUp:`
			`out (SDC_PORT_CSHIGH), a`
			`ld b, 10 ; 10 * 8 == 80`
			`ld a, 0xff`
			`.loop:`
			`out (SDC_PORT_SPI), a`
			`nop`
			`djnz .loop`
			`ret`

			`; Initiate SPI exchange with the SD card. A is the data to send. Received data`
			`; is placed in A.`
			`sdcSendRecv:`
			`out (SDC_PORT_SPI), a`
			`nop`
			`nop`
			`in a, (SDC_PORT_SPI)`
			`nop`
			`nop`
			`ret`

			`; sdcSendRecv 0xff until the response is something else than 0xff for a maximum`
			`; of 20 times. Returns 0xff if no response.`
			`sdcWaitResp:`
			`push bc`
			`ld b, 20`
			`.loop:`
			`ld a, 0xff`
			`call sdcSendRecv`
			`inc a ; if 0xff, it's going to become zero`
			`jr nz, .end ; not zero? good, that's our command`
			`djnz .loop`
			`.end:`
			`; whether we had a success or failure, we return the result.`
			`; But first, let's bring it back to its original value.`
			`dec a`
			`pop bc`
			`ret`

			`; Sends a command to the SD card, along with arguments and specified CRC fields.`
			`; (CRC is only needed in initial commands though).`
			`; A: Command to send`
			`; H: Arg 1 (MSB)`
			`; L: Arg 2`
			`; D: Arg 3`
			`; E: Arg 4 (LSB)`
			`; C: CRC`
			`;`
			`; Returns R1 response in A.`
			`;`
			`; This does not handle CS. You have to select/deselect the card outside this`
			`; routine.`
			`sdcCmd:`
			`; Wait until ready to receive commands`
			`push af`
			`call sdcWaitResp`
			`pop af`

			`call sdcSendRecv`
			`; Arguments`
			`ld a, h`
			`call sdcSendRecv`
			`ld a, l`
			`call sdcSendRecv`
			`ld a, d`
			`call sdcSendRecv`
			`ld a, e`
			`call sdcSendRecv`
			`; send CRC`
			`ld a, c`
			`call sdcSendRecv`

			`; And now we just have to wait for a valid response...`
			`call sdcWaitResp`
			`ret`

			`; Send a command that expects a R1 response, handling CS.`
			`sdcCmdR1:`
			`out (SDC_PORT_CSLOW), a`
			`call sdcCmd`
			`out (SDC_PORT_CSHIGH), a`
			`ret`

			`; Send a command that expects a R7 response, handling CS. A R7 is a R1 followed`
			`; by 4 bytes. Those 4 bytes are returned in HL/DE in the same order as in`
			`; sdcCmd.`
			`sdcCmdR7:`
			`out (SDC_PORT_CSLOW), a`
			`call sdcCmd`

			`; We have our R1 response in A. Let's try reading the next 4 bytes in`
			`; case we have a R3.`
			`push af`
			`ld a, 0xff`
			`call sdcSendRecv`
			`ld h, a`
			`ld a, 0xff`
			`call sdcSendRecv`
			`ld l, a`
			`ld a, 0xff`
			`call sdcSendRecv`
			`ld d, a`
			`ld a, 0xff`
			`call sdcSendRecv`
			`ld e, a`
			`pop af`

			`out (SDC_PORT_CSHIGH), a`
			`ret`
parts/z80/sdc: add sdcInitialize Also, adjust SD card recipe. Straightforward initialization and read! 2019-05-09 06:03:54 +10:00
			`; Initialize a SD card. This should be called at least 1ms after the powering`
			`; up of the card. Sets result code in A. Zero means success, non-zero means`
			`; error.`
			`sdcInitialize:`
			`push hl`
			`push de`
			`push bc`
			`call sdcWakeUp`

			`; Call CMD0 and expect a 0x01 response (card idle)`
			`; This should be called multiple times. We're actually expected to.`
			`; Let's call this for a maximum of 10 times.`
			`ld b, 10`
			`.loop1:`
			`ld a, 0b01000000 ; CMD0`
			`ld hl, 0`
			`ld de, 0`
			`ld c, 0x95`
			`call sdcCmdR1`
			`cp 0x01`
			`jp z, .cmd0ok`
			`djnz .loop1`
			`; Nothing? error`
			`jr .error`
			`.cmd0ok:`

			`; Then comes the CMD8. We send it with a 0x01aa argument and expect`
			`; a 0x01aa argument back, along with a 0x01 R1 response.`
			`ld a, 0b01001000 ; CMD8`
			`ld hl, 0`
			`ld de, 0x01aa`
			`ld c, 0x87`
			`call sdcCmdR7`
			`cp 0x01`
			`jr nz, .error`
			`xor a`
			`cp h ; H is zero`
			`jr nz, .error`
			`cp l ; L is zero`
			`jr nz, .error`
			`ld a, d`
			`cp 0x01`
			`jp nz, .error`
			`ld a, e`
			`cp 0xaa`
			`jr nz, .error`

			`; Now we need to repeatedly run CMD55+CMD41 (0x40000000) until we`
			`; the card goes out of idle mode, that is, when it stops sending us`
			`; 0x01 response and send us 0x00 instead. Any other response means that`
			`; initialization failed.`
			`.loop2:`
			`ld a, 0b01110111 ; CMD55`
			`ld hl, 0`
			`ld de, 0`
			`call sdcCmdR1`
			`cp 0x01`
			`jr nz, .error`
			`ld a, 0b01101001 ; CMD41 (0x40000000)`
			`ld hl, 0x4000`
			`ld de, 0x0000`
			`call sdcCmdR1`
			`cp 0x01`
			`jr z, .loop2`
			`or a ; cp 0`
			`jr nz, .error`
			`; Success! out of idle mode!`
			`; At this point, you are ready to read and write data.`
			`jr .success`

			`.error:`
			`ld a, 0x01`
			`jr .end`

			`.success:`
			`xor a`
			`.end:`
			`pop bc`
			`pop de`
			`pop hl`
			`ret`