client: working on the client

Signed-off-by: Sean Cross <sean@xobs.io>
This commit is contained in:
Sean Cross 2019-03-10 15:25:33 +08:00
parent 13360015db
commit c98017cbc9
3 changed files with 204 additions and 60 deletions

View File

@ -224,87 +224,183 @@ static inline void uart_phy_tuning_word_write(unsigned int value) {
/* usb */
#define CSR_USB_BASE 0xe0004800
#define CSR_USB_BYTE_COUNT_ADDR 0xe0004800
#define CSR_USB_BYTE_COUNT_SIZE 1
static inline unsigned char usb_byte_count_read(void) {
#define CSR_USB_PULLUP_OUT_ADDR 0xe0004800
#define CSR_USB_PULLUP_OUT_SIZE 1
static inline unsigned char usb_pullup_out_read(void) {
unsigned char r = csr_readl(0xe0004800);
return r;
}
#define CSR_USB_OBUF_HEAD_ADDR 0xe0004804
#define CSR_USB_OBUF_HEAD_SIZE 1
static inline unsigned char usb_obuf_head_read(void) {
static inline void usb_pullup_out_write(unsigned char value) {
csr_writel(value, 0xe0004800);
}
#define CSR_USB_EP_0_OUT_EV_STATUS_ADDR 0xe0004804
#define CSR_USB_EP_0_OUT_EV_STATUS_SIZE 1
static inline unsigned char usb_ep_0_out_ev_status_read(void) {
unsigned char r = csr_readl(0xe0004804);
return r;
}
static inline void usb_obuf_head_write(unsigned char value) {
static inline void usb_ep_0_out_ev_status_write(unsigned char value) {
csr_writel(value, 0xe0004804);
}
#define CSR_USB_OBUF_EMPTY_ADDR 0xe0004808
#define CSR_USB_OBUF_EMPTY_SIZE 1
static inline unsigned char usb_obuf_empty_read(void) {
#define CSR_USB_EP_0_OUT_EV_PENDING_ADDR 0xe0004808
#define CSR_USB_EP_0_OUT_EV_PENDING_SIZE 1
static inline unsigned char usb_ep_0_out_ev_pending_read(void) {
unsigned char r = csr_readl(0xe0004808);
return r;
}
#define CSR_USB_ARM_ADDR 0xe000480c
#define CSR_USB_ARM_SIZE 1
static inline unsigned char usb_arm_read(void) {
static inline void usb_ep_0_out_ev_pending_write(unsigned char value) {
csr_writel(value, 0xe0004808);
}
#define CSR_USB_EP_0_OUT_EV_ENABLE_ADDR 0xe000480c
#define CSR_USB_EP_0_OUT_EV_ENABLE_SIZE 1
static inline unsigned char usb_ep_0_out_ev_enable_read(void) {
unsigned char r = csr_readl(0xe000480c);
return r;
}
static inline void usb_arm_write(unsigned char value) {
static inline void usb_ep_0_out_ev_enable_write(unsigned char value) {
csr_writel(value, 0xe000480c);
}
#define CSR_USB_IBUF_HEAD_ADDR 0xe0004810
#define CSR_USB_IBUF_HEAD_SIZE 1
static inline unsigned char usb_ibuf_head_read(void) {
#define CSR_USB_EP_0_OUT_LAST_TOK_ADDR 0xe0004810
#define CSR_USB_EP_0_OUT_LAST_TOK_SIZE 1
static inline unsigned char usb_ep_0_out_last_tok_read(void) {
unsigned char r = csr_readl(0xe0004810);
return r;
}
static inline void usb_ibuf_head_write(unsigned char value) {
csr_writel(value, 0xe0004810);
}
#define CSR_USB_IBUF_EMPTY_ADDR 0xe0004814
#define CSR_USB_IBUF_EMPTY_SIZE 1
static inline unsigned char usb_ibuf_empty_read(void) {
#define CSR_USB_EP_0_OUT_RESPOND_ADDR 0xe0004814
#define CSR_USB_EP_0_OUT_RESPOND_SIZE 1
static inline unsigned char usb_ep_0_out_respond_read(void) {
unsigned char r = csr_readl(0xe0004814);
return r;
}
#define CSR_USB_PULLUP_OUT_ADDR 0xe0004818
#define CSR_USB_PULLUP_OUT_SIZE 1
static inline unsigned char usb_pullup_out_read(void) {
static inline void usb_ep_0_out_respond_write(unsigned char value) {
csr_writel(value, 0xe0004814);
}
#define CSR_USB_EP_0_OUT_DTB_ADDR 0xe0004818
#define CSR_USB_EP_0_OUT_DTB_SIZE 1
static inline unsigned char usb_ep_0_out_dtb_read(void) {
unsigned char r = csr_readl(0xe0004818);
return r;
}
static inline void usb_pullup_out_write(unsigned char value) {
static inline void usb_ep_0_out_dtb_write(unsigned char value) {
csr_writel(value, 0xe0004818);
}
#define CSR_USB_EV_STATUS_ADDR 0xe000481c
#define CSR_USB_EV_STATUS_SIZE 1
static inline unsigned char usb_ev_status_read(void) {
#define CSR_USB_EP_0_OUT_OBUF_HEAD_ADDR 0xe000481c
#define CSR_USB_EP_0_OUT_OBUF_HEAD_SIZE 1
static inline unsigned char usb_ep_0_out_obuf_head_read(void) {
unsigned char r = csr_readl(0xe000481c);
return r;
}
static inline void usb_ev_status_write(unsigned char value) {
static inline void usb_ep_0_out_obuf_head_write(unsigned char value) {
csr_writel(value, 0xe000481c);
}
#define CSR_USB_EV_PENDING_ADDR 0xe0004820
#define CSR_USB_EV_PENDING_SIZE 1
static inline unsigned char usb_ev_pending_read(void) {
#define CSR_USB_EP_0_OUT_OBUF_EMPTY_ADDR 0xe0004820
#define CSR_USB_EP_0_OUT_OBUF_EMPTY_SIZE 1
static inline unsigned char usb_ep_0_out_obuf_empty_read(void) {
unsigned char r = csr_readl(0xe0004820);
return r;
}
static inline void usb_ev_pending_write(unsigned char value) {
csr_writel(value, 0xe0004820);
}
#define CSR_USB_EV_ENABLE_ADDR 0xe0004824
#define CSR_USB_EV_ENABLE_SIZE 1
static inline unsigned char usb_ev_enable_read(void) {
#define CSR_USB_EP_0_IN_EV_STATUS_ADDR 0xe0004824
#define CSR_USB_EP_0_IN_EV_STATUS_SIZE 1
static inline unsigned char usb_ep_0_in_ev_status_read(void) {
unsigned char r = csr_readl(0xe0004824);
return r;
}
static inline void usb_ev_enable_write(unsigned char value) {
static inline void usb_ep_0_in_ev_status_write(unsigned char value) {
csr_writel(value, 0xe0004824);
}
#define CSR_USB_EP_0_IN_EV_PENDING_ADDR 0xe0004828
#define CSR_USB_EP_0_IN_EV_PENDING_SIZE 1
static inline unsigned char usb_ep_0_in_ev_pending_read(void) {
unsigned char r = csr_readl(0xe0004828);
return r;
}
static inline void usb_ep_0_in_ev_pending_write(unsigned char value) {
csr_writel(value, 0xe0004828);
}
#define CSR_USB_EP_0_IN_EV_ENABLE_ADDR 0xe000482c
#define CSR_USB_EP_0_IN_EV_ENABLE_SIZE 1
static inline unsigned char usb_ep_0_in_ev_enable_read(void) {
unsigned char r = csr_readl(0xe000482c);
return r;
}
static inline void usb_ep_0_in_ev_enable_write(unsigned char value) {
csr_writel(value, 0xe000482c);
}
#define CSR_USB_EP_0_IN_LAST_TOK_ADDR 0xe0004830
#define CSR_USB_EP_0_IN_LAST_TOK_SIZE 1
static inline unsigned char usb_ep_0_in_last_tok_read(void) {
unsigned char r = csr_readl(0xe0004830);
return r;
}
#define CSR_USB_EP_0_IN_RESPOND_ADDR 0xe0004834
#define CSR_USB_EP_0_IN_RESPOND_SIZE 1
static inline unsigned char usb_ep_0_in_respond_read(void) {
unsigned char r = csr_readl(0xe0004834);
return r;
}
static inline void usb_ep_0_in_respond_write(unsigned char value) {
csr_writel(value, 0xe0004834);
}
#define CSR_USB_EP_0_IN_DTB_ADDR 0xe0004838
#define CSR_USB_EP_0_IN_DTB_SIZE 1
static inline unsigned char usb_ep_0_in_dtb_read(void) {
unsigned char r = csr_readl(0xe0004838);
return r;
}
static inline void usb_ep_0_in_dtb_write(unsigned char value) {
csr_writel(value, 0xe0004838);
}
#define CSR_USB_EP_0_IN_IBUF_HEAD_ADDR 0xe000483c
#define CSR_USB_EP_0_IN_IBUF_HEAD_SIZE 1
static inline unsigned char usb_ep_0_in_ibuf_head_read(void) {
unsigned char r = csr_readl(0xe000483c);
return r;
}
static inline void usb_ep_0_in_ibuf_head_write(unsigned char value) {
csr_writel(value, 0xe000483c);
}
#define CSR_USB_EP_0_IN_IBUF_EMPTY_ADDR 0xe0004840
#define CSR_USB_EP_0_IN_IBUF_EMPTY_SIZE 1
static inline unsigned char usb_ep_0_in_ibuf_empty_read(void) {
unsigned char r = csr_readl(0xe0004840);
return r;
}
#define CSR_USB_USB_TRANSFER_O_PID_ADDR 0xe0004844
#define CSR_USB_USB_TRANSFER_O_PID_SIZE 1
static inline unsigned char usb_usb_transfer_o_pid_read(void) {
unsigned char r = csr_readl(0xe0004844);
return r;
}
#define CSR_USB_USB_TRANSFER_ERROR_STATE_ADDR 0xe0004848
#define CSR_USB_USB_TRANSFER_ERROR_STATE_SIZE 1
static inline unsigned char usb_usb_transfer_error_state_read(void) {
unsigned char r = csr_readl(0xe0004848);
return r;
}
#define CSR_USB_USB_TRANSFER_ERROR_PID_ADDR 0xe000484c
#define CSR_USB_USB_TRANSFER_ERROR_PID_SIZE 1
static inline unsigned char usb_usb_transfer_error_pid_read(void) {
unsigned char r = csr_readl(0xe000484c);
return r;
}
#define CSR_USB_DBG_LWH_ADDR 0xe0004850
#define CSR_USB_DBG_LWH_SIZE 1
static inline unsigned char usb_dbg_lwh_read(void) {
unsigned char r = csr_readl(0xe0004850);
return r;
}
#define CSR_USB_DBG_LWD_ADDR 0xe0004854
#define CSR_USB_DBG_LWD_SIZE 1
static inline unsigned char usb_dbg_lwd_read(void) {
unsigned char r = csr_readl(0xe0004854);
return r;
}
#define CSR_USB_DBG_LFP_ADDR 0xe0004858
#define CSR_USB_DBG_LFP_SIZE 1
static inline unsigned char usb_dbg_lfp_read(void) {
unsigned char r = csr_readl(0xe0004858);
return r;
}
/* constants */
#define NMI_INTERRUPT 0

View File

@ -70,7 +70,7 @@ int main(int argc, char **argv)
// uart_read();
printf("Enabling USB\n");
usb_connect();
printf("USB enabled, waiting for packet...\n");
printf("USB enabled.\n");
// usb_print_status();
int last = 0;
static uint8_t bfr[12];
@ -81,14 +81,16 @@ int main(int argc, char **argv)
printf("USB %d IRQ happened\n", last);
}
usb_poll();
/*
printf("Press any key to send... ");
uart_read();
printf("Sending... ");
bfr[0] = ~0;
bfr[1] = 0;
bfr[0] = 0;
bfr[1] = ~0;
bfr[2] = 0;
usb_send(NULL, 0, bfr, 3);
usb_send(NULL, 0, bfr, 1);
printf("Sent\n");
*/
}
return 0;
}

View File

@ -23,6 +23,7 @@ enum CONTROL_STATE
#define NUM_BUFFERS 4
#define BUFFER_SIZE 64
#define EP_INTERVAL_MS 6
static const char hex[] = "0123456789abcdef";
enum epfifo_response {
EPF_ACK = 0,
@ -35,17 +36,18 @@ enum epfifo_response {
#define USB_EV_PACKET 2
void usb_connect(void) {
usb_pullup_out_write(1);
// By default, it wants to respond with NAK.
usb_ep_0_out_respond_write(EPF_ACK);
usb_ep_0_in_respond_write(EPF_ACK);
usb_ep_0_out_ev_pending_write(usb_ep_0_out_ev_enable_read());
usb_ep_0_in_ev_pending_write(usb_ep_0_in_ev_pending_read());
usb_ep_0_out_ev_enable_write(USB_EV_PACKET | USB_EV_ERROR);
usb_ep_0_in_ev_enable_write(USB_EV_PACKET | USB_EV_ERROR);
// By default, it wants to respond with NAK.
usb_ep_0_out_respond_write(EPF_ACK);
usb_ep_0_in_respond_write(EPF_ACK);
usb_pullup_out_write(1);
irq_setmask(irq_getmask() | (1 << USB_INTERRUPT));
}
@ -89,8 +91,18 @@ static int queue_more_data(int epnum) {
int usb_send(struct usb_device *dev, int epnum, const void *data, int total_count) {
(void)dev;
// Don't allow requeueing
if (usb_ep_0_in_respond_read() != EPF_NAK)
// if (usb_ep_0_in_respond_read() != EPF_NAK)
// return -1;
if (!usb_ep_0_in_ibuf_empty_read()) {
printf("IBUF isn't empty. Error? %d\n", usb_usb_transfer_error_state_read());
return -1;
}
/*
while (!usb_ep_0_in_ibuf_empty_read()) {
printf("Emptying out ibuf...\n");
usb_ep_0_in_ibuf_head_read();
}
*/
current_data = (uint8_t *)data;
current_length = total_count;
current_offset = 0;
@ -100,10 +112,21 @@ int usb_send(struct usb_device *dev, int epnum, const void *data, int total_coun
}
void usb_isr(void) {
irq_count++;
#if 0
uint8_t ep0o_pending = usb_ep_0_out_ev_pending_read();
uint8_t ep0i_pending = usb_ep_0_in_ev_pending_read();
while (!usb_ep_0_out_obuf_empty_read()) {
usb_ep_0_out_obuf_head_write(0);
}
usb_ep_0_out_respond_write(EPF_ACK);
usb_ep_0_in_respond_write(EPF_ACK);
usb_ep_0_out_ev_pending_write(ep0o_pending);
usb_ep_0_in_ev_pending_write(ep0i_pending);
#else
irq_count++;
uint8_t ep0o_pending = usb_ep_0_out_ev_pending_read();
uint8_t ep0i_pending = usb_ep_0_in_ev_pending_read();
printf(">> %02x %02x <<\n", ep0o_pending, ep0i_pending);
// We got an OUT or a SETUP packet. Copy it to usb_ep0out_buffer
// and clear the "pending" bit.
@ -118,7 +141,16 @@ void usb_isr(void) {
usb_ep_0_out_ev_pending_write(ep0o_pending);
if (byte_count) {
printf("read %d bytes\n", byte_count);
printf("read %d bytes: [", byte_count);
unsigned int i;
for (i = 0; i < byte_count; i++) {
uart_write(' ');
uart_write(hex[(obuf[i] >> 4) & 0xf]);
uart_write(hex[obuf[i] & (0xf)]);
}
uart_write(' ]');
uart_write('\r');
uart_write('\n');
usb_ep0out_buffer_len[usb_ep0out_wr_ptr] = byte_count;
usb_ep0out_wr_ptr = (usb_ep0out_wr_ptr + 1) & (EP0OUT_BUFFERS-1);
}
@ -144,9 +176,10 @@ void usb_isr(void) {
usb_ep_0_out_respond_write(EPF_ACK);
}
}
else
usb_ep_0_in_respond_write(EPF_NAK);
}
printf(">> %02x %02x <<\n", ep0o_pending, ep0i_pending);
#endif
return;
}
@ -165,6 +198,7 @@ int usb_ack(struct usb_device *dev, int epnum) {
}
int usb_err(struct usb_device *dev, int epnum) {
printf("STALLING!!!\n");
usb_ep_0_out_respond_write(EPF_STALL);
usb_ep_0_in_respond_write(EPF_STALL);
}
@ -173,9 +207,14 @@ int usb_recv(struct usb_device *dev, void *buffer, unsigned int buffer_len) {
return;
}
static const char hex[] = "0123456789abcdef";
void usb_poll(void) {
static int last_error_count;
int this_error_count = usb_usb_transfer_error_state_read();
if (last_error_count != this_error_count) {
printf("USB TRANSFER ERROR STATE # %d!! WaitHand? %d WaitData? %d PID: %02x (was: %02x, full: %02x)\n", this_error_count, usb_dbg_lwh_read(), usb_dbg_lwd_read(), usb_usb_transfer_o_pid_read(), usb_usb_transfer_error_pid_read(), usb_dbg_lfp_read());
last_error_count = this_error_count;
}
// If some data was received, then process it.
if (usb_ep0out_rd_ptr != usb_ep0out_wr_ptr) {
const struct usb_setup_request *request = (const struct usb_setup_request *)(usb_ep0out_buffer[usb_ep0out_rd_ptr]);
@ -184,6 +223,10 @@ void usb_poll(void) {
usb_ep0out_buffer_len[usb_ep0out_rd_ptr] = 0;
usb_ep0out_rd_ptr = (usb_ep0out_rd_ptr + 1) & (EP0OUT_BUFFERS-1);
}
if ((usb_ep_0_in_respond_read() == EPF_NAK) && (current_data))
queue_more_data(0);
// Cancel any pending transfers
if ((control_state == IN_DATA) && usb_ep_0_in_ibuf_empty_read()) {
printf("state is IN_DATA but ibuf is empty?\n");
@ -192,9 +235,12 @@ void usb_poll(void) {
usb_ep_0_out_obuf_head_write(0);
control_state = WAIT_SETUP;
}
if (!usb_ep_0_out_obuf_empty_read()) {
printf("obuf not empty\n");
}
// if (!usb_ep_0_out_obuf_empty_read()) {
// printf("FATAL: obuf not empty, and pending is %d\n", usb_ep_0_out_ev_pending_read());
// printf("HALT");
// while (1)
// ;
// }
// if (!usb_ep_0_in_ibuf_empty_read()) {
// usb_ep_0_in_ibuf_head_write(0);
// }