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[/] [openrisc/] [trunk/] [rtos/] [ecos-3.0/] [packages/] [devs/] [touch/] [arm/] [aaed2000/] [current/] [src/] [aaed2000_ts.c] - Rev 786
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//========================================================================== // // aaed2000_ts.c // // Touchscreen driver for the Agilent aaed2000 // //========================================================================== // ####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, Inc. // // eCos is free software; you can redistribute it and/or modify it under // the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 or (at your option) any later // version. // // eCos is distributed in the hope that it will be useful, but WITHOUT // ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License // for more details. // // You should have received a copy of the GNU General Public License // along with eCos; if not, write to the Free Software Foundation, Inc., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. // // As a special exception, if other files instantiate templates or use // macros or inline functions from this file, or you compile this file // and link it with other works to produce a work based on this file, // this file does not by itself cause the resulting work to be covered by // the GNU General Public License. However the source code for this file // must still be made available in accordance with section (3) of the GNU // General Public License v2. // // This exception does not invalidate any other reasons why a work based // on this file might be covered by the GNU General Public License. // ------------------------------------------- // ####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): gthomas // Contributors: gthomas // Date: 2002-03-05 // Purpose: // Description: Touchscreen driver for Agilent AAED2000 // //####DESCRIPTIONEND#### // //========================================================================== #include <pkgconf/devs_touch_aaed2000.h> #include <cyg/kernel/kapi.h> #include <cyg/hal/hal_io.h> #include <cyg/hal/hal_arch.h> #include <cyg/hal/drv_api.h> #include <cyg/hal/hal_intr.h> #include <cyg/hal/aaed2000.h> #include <cyg/infra/cyg_type.h> #include <cyg/infra/cyg_ass.h> #include <cyg/infra/diag.h> #include <cyg/fileio/fileio.h> // For select() functionality static cyg_selinfo ts_select_info; static cyg_bool ts_select_active; #include <cyg/io/devtab.h> /* ADS7846 flags */ #define ADS_START (1 << 7) #define ADS_MEASURE_Y (0x01 << 4) #define ADS_MEASURE_X (0x05 << 4) #define ADS_MODE_12_BIT 0 #define ADS_PD0 0 // Misc constants #define TS_INT (1<<0) #define X_THRESHOLD 0x80 #define Y_THRESHOLD 0x80 // Functions in this module static Cyg_ErrNo ts_read(cyg_io_handle_t handle, void *buffer, cyg_uint32 *len); static cyg_bool ts_select(cyg_io_handle_t handle, cyg_uint32 which, cyg_addrword_t info); static Cyg_ErrNo ts_set_config(cyg_io_handle_t handle, cyg_uint32 key, const void *buffer, cyg_uint32 *len); static Cyg_ErrNo ts_get_config(cyg_io_handle_t handle, cyg_uint32 key, void *buffer, cyg_uint32 *len); static bool ts_init(struct cyg_devtab_entry *tab); static Cyg_ErrNo ts_lookup(struct cyg_devtab_entry **tab, struct cyg_devtab_entry *st, const char *name); CHAR_DEVIO_TABLE(aaed2000_ts_handlers, NULL, // Unsupported write() function ts_read, ts_select, ts_get_config, ts_set_config); CHAR_DEVTAB_ENTRY(aaed2000_ts_device, CYGDAT_DEVS_TOUCH_AAED2000_NAME, NULL, // Base device name &aaed2000_ts_handlers, ts_init, ts_lookup, NULL); // Private data pointer struct _event { short button_state; short xPos, yPos; short _unused; }; #define MAX_EVENTS CYGNUM_DEVS_TOUCH_AAED2000_EVENT_BUFFER_SIZE static int num_events; static int _event_put, _event_get; static struct _event _events[MAX_EVENTS]; static bool _is_open = false; #ifdef DEBUG_RAW_EVENTS static unsigned char _ts_buf[512]; static int _ts_buf_ptr = 0; #endif #define STACK_SIZE CYGNUM_HAL_STACK_SIZE_TYPICAL static char ts_scan_stack[STACK_SIZE]; static cyg_thread ts_scan_thread_data; static cyg_handle_t ts_scan_thread_handle; #define SCAN_FREQ 20 // Hz //#define SCAN_FREQ 5 // Hz #define SCAN_DELAY ((1000/SCAN_FREQ)/10) typedef struct { short min; short max; short span; } bounds; static bounds xBounds = {1024, 0, 1024}; static bounds yBounds = {1024, 0, 1024}; static Cyg_ErrNo ts_read(cyg_io_handle_t handle, void *buffer, cyg_uint32 *len) { struct _event *ev; int tot = *len; unsigned char *bp = (unsigned char *)buffer; cyg_scheduler_lock(); // Prevent interaction with DSR code while (tot >= sizeof(struct _event)) { if (num_events > 0) { ev = &_events[_event_get++]; if (_event_get == MAX_EVENTS) { _event_get = 0; } // Self calibrate if (ev->xPos > xBounds.max) xBounds.max = ev->xPos; if (ev->xPos < xBounds.min) xBounds.min = ev->xPos; if (ev->yPos > yBounds.max) yBounds.max = ev->yPos; if (ev->yPos < yBounds.min) yBounds.min = ev->yPos; if ((xBounds.span = xBounds.max - xBounds.min) <= 1) { xBounds.span = 1; } if ((yBounds.span = yBounds.max - yBounds.min) <= 1) { yBounds.span = 1; } // Scale values - done here so these potentially lengthy // operations take place outside of interrupt processing #ifdef DEBUG diag_printf("Raw[%d,%d], X[%d,%d,%d], Y[%d,%d,%d]", ev->xPos, ev->yPos, xBounds.max, xBounds.min, xBounds.span, yBounds.max, yBounds.min, yBounds.span); #endif ev->xPos = 640 - (((xBounds.max - ev->xPos) * 640) / xBounds.span); ev->yPos = 480 - (((yBounds.max - ev->yPos) * 480) / yBounds.span); #ifdef DEBUG diag_printf(", Cooked[%d,%d]\n", ev->xPos, ev->yPos); #endif memcpy(bp, ev, sizeof(*ev)); bp += sizeof(*ev); tot -= sizeof(*ev); num_events--; } else { break; // No more events } } cyg_scheduler_unlock(); // Allow DSRs again *len -= tot; return ENOERR; } static cyg_bool ts_select(cyg_io_handle_t handle, cyg_uint32 which, cyg_addrword_t info) { if (which == CYG_FREAD) { cyg_scheduler_lock(); // Prevent interaction with DSR code if (num_events > 0) { cyg_scheduler_unlock(); // Reallow interaction with DSR code return true; } if (!ts_select_active) { ts_select_active = true; cyg_selrecord(info, &ts_select_info); } cyg_scheduler_unlock(); // Reallow interaction with DSR code } return false; } static Cyg_ErrNo ts_set_config(cyg_io_handle_t handle, cyg_uint32 key, const void *buffer, cyg_uint32 *len) { return EINVAL; } static Cyg_ErrNo ts_get_config(cyg_io_handle_t handle, cyg_uint32 key, void *buffer, cyg_uint32 *len) { return EINVAL; } static bool ts_init(struct cyg_devtab_entry *tab) { cyg_uint32 _dummy; // Initialize SSP interface #if 0 while (*(volatile cyg_uint32 *)AAEC_SSP_SR & AAEC_SSP_SR_RNE) { _dummy = *(volatile cyg_uint32 *)AAEC_SSP_DR; // Drain FIFO } #endif *(volatile cyg_uint32 *)AAEC_SSP_CR0 = (1 << AAEC_SSP_CR0_SSE) | // SSP enable (37 << AAEC_SSP_CR0_SCR) | // Serial clock rate (AAEC_SSP_CR0_FRF_NAT << AAEC_SSP_CR0_FRF) | // MicroWire ((12-1) << AAEC_SSP_CR0_SIZE); // 12 bit words *(volatile cyg_uint32 *)AAEC_SSP_CR1 = (1 << AAEC_SSP_CR1_FEN); // Enable FIFO *(volatile cyg_uint32 *)AAEC_SSP_CPSR = 2; // Clock prescale *(volatile cyg_uint32 *)AAEC_PFDDR &= ~(1<<0); // TS uses port F bit 0 cyg_drv_interrupt_acknowledge(CYGNUM_HAL_INTERRUPT_TS); cyg_selinit(&ts_select_info); return true; } static cyg_uint32 read_ts(int axis) { cyg_uint32 res; *(volatile cyg_uint32 *)AAEC_SSP_DR = (axis | ADS_START | ADS_MODE_12_BIT | ADS_PD0); *(volatile cyg_uint32 *)AAEC_SSP_DR = (axis | ADS_START | ADS_MODE_12_BIT); // Wait for data while ((*(volatile cyg_uint32 *)AAEC_SSP_SR & AAEC_SSP_SR_RNE) == 0); res = *(volatile cyg_uint32 *)AAEC_SSP_DR; // ignore first datum // Wait for data while ((*(volatile cyg_uint32 *)AAEC_SSP_SR & AAEC_SSP_SR_RNE) == 0); res = *(volatile cyg_uint32 *)AAEC_SSP_DR; return res; } static void ts_scan(cyg_addrword_t param) { short lastX, lastY; short x, y; struct _event *ev; bool pen_down; diag_printf("Touch Screen thread started\n"); // Discard the first sample - it's always 0 x = read_ts(ADS_MEASURE_X); y = read_ts(ADS_MEASURE_Y); lastX = lastY = -1; pen_down = false; while (true) { cyg_thread_delay(SCAN_DELAY); if ((*(volatile cyg_uint32 *)AAEC_PFDR & TS_INT) == 0) { // Pen is down x = read_ts(ADS_MEASURE_X); y = read_ts(ADS_MEASURE_Y); // diag_printf("X = %x, Y = %x\n", x, y); if ((x < X_THRESHOLD) || (y < Y_THRESHOLD)) { // Ignore 'bad' samples continue; } lastX = x; lastY = y; pen_down = true; } else { if (pen_down) { // Capture first 'up' event pen_down = false; x = lastX; y = lastY; } else { continue; // Nothing new to report } } if (num_events < MAX_EVENTS) { num_events++; ev = &_events[_event_put++]; if (_event_put == MAX_EVENTS) { _event_put = 0; } ev->button_state = pen_down ? 0x04 : 0x00; ev->xPos = x; ev->yPos = y; if (ts_select_active) { ts_select_active = false; cyg_selwakeup(&ts_select_info); } } #ifdef DEBUG_RAW_EVENTS memcpy(&_ts_buf[_ts_buf_ptr], pkt->data, 8); _ts_buf_ptr += 8; if (_ts_buf_ptr == 512) { diag_printf("TS handler\n"); diag_dump_buf(_ts_buf, 512); _ts_buf_ptr = 0; } #endif } } static Cyg_ErrNo ts_lookup(struct cyg_devtab_entry **tab, struct cyg_devtab_entry *st, const char *name) { if (!_is_open) { _is_open = true; cyg_thread_create(1, // Priority ts_scan, // entry 0, // entry parameter "Touch Screen scan", // Name &ts_scan_stack[0], // Stack STACK_SIZE, // Size &ts_scan_thread_handle, // Handle &ts_scan_thread_data // Thread data structure ); cyg_thread_resume(ts_scan_thread_handle); // Start it } return ENOERR; }