/* * Epson S1D13744/S1D13745 (Blizzard/Hailstorm/Tornado) LCD/TV controller. * * Copyright (C) 2008 Nokia Corporation * Written by Andrzej Zaborowski * * This program 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) version 3 of the License. * * This program 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 this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "qemu-common.h" #include "sysemu.h" #include "console.h" #include "devices.h" #include "vga_int.h" #include "pixel_ops.h" typedef void (*blizzard_fn_t)(uint8_t *, const uint8_t *, unsigned int); struct blizzard_s { uint8_t reg; uint32_t addr; int swallow; int pll; int pll_range; int pll_ctrl; uint8_t pll_mode; uint8_t clksel; int memenable; int memrefresh; uint8_t timing[3]; int priority; uint8_t lcd_config; int x; int y; int skipx; int skipy; uint8_t hndp; uint8_t vndp; uint8_t hsync; uint8_t vsync; uint8_t pclk; uint8_t u; uint8_t v; uint8_t yrc[2]; int ix[2]; int iy[2]; int ox[2]; int oy[2]; int enable; int blank; int bpp; int invalidate; int mx[2]; int my[2]; uint8_t mode; uint8_t effect; uint8_t iformat; uint8_t source; DisplayState *state; blizzard_fn_t *line_fn_tab[2]; void *fb; uint8_t hssi_config[3]; uint8_t tv_config; uint8_t tv_timing[4]; uint8_t vbi; uint8_t tv_x; uint8_t tv_y; uint8_t tv_test; uint8_t tv_filter_config; uint8_t tv_filter_idx; uint8_t tv_filter_coeff[0x20]; uint8_t border_r; uint8_t border_g; uint8_t border_b; uint8_t gamma_config; uint8_t gamma_idx; uint8_t gamma_lut[0x100]; uint8_t matrix_ena; uint8_t matrix_coeff[0x12]; uint8_t matrix_r; uint8_t matrix_g; uint8_t matrix_b; uint8_t pm; uint8_t status; uint8_t rgbgpio_dir; uint8_t rgbgpio; uint8_t gpio_dir; uint8_t gpio; uint8_t gpio_edge[2]; uint8_t gpio_irq; uint8_t gpio_pdown; struct { int x; int y; int dx; int dy; int len; int buflen; void *buf; void *data; uint16_t *ptr; int angle; int pitch; blizzard_fn_t line_fn; } data; }; /* Bytes(!) per pixel */ static const int blizzard_iformat_bpp[0x10] = { 0, 2, /* RGB 5:6:5*/ 3, /* RGB 6:6:6 mode 1 */ 3, /* RGB 8:8:8 mode 1 */ 0, 0, 4, /* RGB 6:6:6 mode 2 */ 4, /* RGB 8:8:8 mode 2 */ 0, /* YUV 4:2:2 */ 0, /* YUV 4:2:0 */ 0, 0, 0, 0, 0, 0, }; static inline void blizzard_rgb2yuv(int r, int g, int b, int *y, int *u, int *v) { *y = 0x10 + ((0x838 * r + 0x1022 * g + 0x322 * b) >> 13); *u = 0x80 + ((0xe0e * b - 0x04c1 * r - 0x94e * g) >> 13); *v = 0x80 + ((0xe0e * r - 0x0bc7 * g - 0x247 * b) >> 13); } static void blizzard_window(struct blizzard_s *s) { uint8_t *src, *dst; int bypp[2]; int bypl[3]; int y; blizzard_fn_t fn = s->data.line_fn; if (!fn) return; if (s->mx[0] > s->data.x) s->mx[0] = s->data.x; if (s->my[0] > s->data.y) s->my[0] = s->data.y; if (s->mx[1] < s->data.x + s->data.dx) s->mx[1] = s->data.x + s->data.dx; if (s->my[1] < s->data.y + s->data.dy) s->my[1] = s->data.y + s->data.dy; bypp[0] = s->bpp; bypp[1] = (ds_get_bits_per_pixel(s->state) + 7) >> 3; bypl[0] = bypp[0] * s->data.pitch; bypl[1] = bypp[1] * s->x; bypl[2] = bypp[0] * s->data.dx; src = s->data.data; dst = s->fb + bypl[1] * s->data.y + bypp[1] * s->data.x; for (y = s->data.dy; y > 0; y --, src += bypl[0], dst += bypl[1]) fn(dst, src, bypl[2]); } static int blizzard_transfer_setup(struct blizzard_s *s) { if (s->source > 3 || !s->bpp || s->ix[1] < s->ix[0] || s->iy[1] < s->iy[0]) return 0; s->data.angle = s->effect & 3; s->data.line_fn = s->line_fn_tab[!!s->data.angle][s->iformat]; s->data.x = s->ix[0]; s->data.y = s->iy[0]; s->data.dx = s->ix[1] - s->ix[0] + 1; s->data.dy = s->iy[1] - s->iy[0] + 1; s->data.len = s->bpp * s->data.dx * s->data.dy; s->data.pitch = s->data.dx; if (s->data.len > s->data.buflen) { s->data.buf = qemu_realloc(s->data.buf, s->data.len); s->data.buflen = s->data.len; } s->data.ptr = s->data.buf; s->data.data = s->data.buf; s->data.len /= 2; return 1; } static void blizzard_reset(struct blizzard_s *s) { s->reg = 0; s->swallow = 0; s->pll = 9; s->pll_range = 1; s->pll_ctrl = 0x14; s->pll_mode = 0x32; s->clksel = 0x00; s->memenable = 0; s->memrefresh = 0x25c; s->timing[0] = 0x3f; s->timing[1] = 0x13; s->timing[2] = 0x21; s->priority = 0; s->lcd_config = 0x74; s->x = 8; s->y = 1; s->skipx = 0; s->skipy = 0; s->hndp = 3; s->vndp = 2; s->hsync = 1; s->vsync = 1; s->pclk = 0x80; s->ix[0] = 0; s->ix[1] = 0; s->iy[0] = 0; s->iy[1] = 0; s->ox[0] = 0; s->ox[1] = 0; s->oy[0] = 0; s->oy[1] = 0; s->yrc[0] = 0x00; s->yrc[1] = 0x30; s->u = 0; s->v = 0; s->iformat = 3; s->source = 0; s->bpp = blizzard_iformat_bpp[s->iformat]; s->hssi_config[0] = 0x00; s->hssi_config[1] = 0x00; s->hssi_config[2] = 0x01; s->tv_config = 0x00; s->tv_timing[0] = 0x00; s->tv_timing[1] = 0x00; s->tv_timing[2] = 0x00; s->tv_timing[3] = 0x00; s->vbi = 0x10; s->tv_x = 0x14; s->tv_y = 0x03; s->tv_test = 0x00; s->tv_filter_config = 0x80; s->tv_filter_idx = 0x00; s->border_r = 0x10; s->border_g = 0x80; s->border_b = 0x80; s->gamma_config = 0x00; s->gamma_idx = 0x00; s->matrix_ena = 0x00; memset(&s->matrix_coeff, 0, sizeof(s->matrix_coeff)); s->matrix_r = 0x00; s->matrix_g = 0x00; s->matrix_b = 0x00; s->pm = 0x02; s->status = 0x00; s->rgbgpio_dir = 0x00; s->gpio_dir = 0x00; s->gpio_edge[0] = 0x00; s->gpio_edge[1] = 0x00; s->gpio_irq = 0x00; s->gpio_pdown = 0xff; } static inline void blizzard_invalidate_display(void *opaque) { struct blizzard_s *s = (struct blizzard_s *) opaque; s->invalidate = 1; } static uint16_t blizzard_reg_read(void *opaque, uint8_t reg) { struct blizzard_s *s = (struct blizzard_s *) opaque; switch (reg) { case 0x00: /* Revision Code */ return 0xa5; case 0x02: /* Configuration Readback */ return 0x83; /* Macrovision OK, CNF[2:0] = 3 */ case 0x04: /* PLL M-Divider */ return (s->pll - 1) | (1 << 7); case 0x06: /* PLL Lock Range Control */ return s->pll_range; case 0x08: /* PLL Lock Synthesis Control 0 */ return s->pll_ctrl & 0xff; case 0x0a: /* PLL Lock Synthesis Control 1 */ return s->pll_ctrl >> 8; case 0x0c: /* PLL Mode Control 0 */ return s->pll_mode; case 0x0e: /* Clock-Source Select */ return s->clksel; case 0x10: /* Memory Controller Activate */ case 0x14: /* Memory Controller Bank 0 Status Flag */ return s->memenable; case 0x18: /* Auto-Refresh Interval Setting 0 */ return s->memrefresh & 0xff; case 0x1a: /* Auto-Refresh Interval Setting 1 */ return s->memrefresh >> 8; case 0x1c: /* Power-On Sequence Timing Control */ return s->timing[0]; case 0x1e: /* Timing Control 0 */ return s->timing[1]; case 0x20: /* Timing Control 1 */ return s->timing[2]; case 0x24: /* Arbitration Priority Control */ return s->priority; case 0x28: /* LCD Panel Configuration */ return s->lcd_config; case 0x2a: /* LCD Horizontal Display Width */ return s->x >> 3; case 0x2c: /* LCD Horizontal Non-display Period */ return s->hndp; case 0x2e: /* LCD Vertical Display Height 0 */ return s->y & 0xff; case 0x30: /* LCD Vertical Display Height 1 */ return s->y >> 8; case 0x32: /* LCD Vertical Non-display Period */ return s->vndp; case 0x34: /* LCD HS Pulse-width */ return s->hsync; case 0x36: /* LCd HS Pulse Start Position */ return s->skipx >> 3; case 0x38: /* LCD VS Pulse-width */ return s->vsync; case 0x3a: /* LCD VS Pulse Start Position */ return s->skipy; case 0x3c: /* PCLK Polarity */ return s->pclk; case 0x3e: /* High-speed Serial Interface Tx Configuration Port 0 */ return s->hssi_config[0]; case 0x40: /* High-speed Serial Interface Tx Configuration Port 1 */ return s->hssi_config[1]; case 0x42: /* High-speed Serial Interface Tx Mode */ return s->hssi_config[2]; case 0x44: /* TV Display Configuration */ return s->tv_config; case 0x46 ... 0x4c: /* TV Vertical Blanking Interval Data bits */ return s->tv_timing[(reg - 0x46) >> 1]; case 0x4e: /* VBI: Closed Caption / XDS Control / Status */ return s->vbi; case 0x50: /* TV Horizontal Start Position */ return s->tv_x; case 0x52: /* TV Vertical Start Position */ return s->tv_y; case 0x54: /* TV Test Pattern Setting */ return s->tv_test; case 0x56: /* TV Filter Setting */ return s->tv_filter_config; case 0x58: /* TV Filter Coefficient Index */ return s->tv_filter_idx; case 0x5a: /* TV Filter Coefficient Data */ if (s->tv_filter_idx < 0x20) return s->tv_filter_coeff[s->tv_filter_idx ++]; return 0; case 0x60: /* Input YUV/RGB Translate Mode 0 */ return s->yrc[0]; case 0x62: /* Input YUV/RGB Translate Mode 1 */ return s->yrc[1]; case 0x64: /* U Data Fix */ return s->u; case 0x66: /* V Data Fix */ return s->v; case 0x68: /* Display Mode */ return s->mode; case 0x6a: /* Special Effects */ return s->effect; case 0x6c: /* Input Window X Start Position 0 */ return s->ix[0] & 0xff; case 0x6e: /* Input Window X Start Position 1 */ return s->ix[0] >> 3; case 0x70: /* Input Window Y Start Position 0 */ return s->ix[0] & 0xff; case 0x72: /* Input Window Y Start Position 1 */ return s->ix[0] >> 3; case 0x74: /* Input Window X End Position 0 */ return s->ix[1] & 0xff; case 0x76: /* Input Window X End Position 1 */ return s->ix[1] >> 3; case 0x78: /* Input Window Y End Position 0 */ return s->ix[1] & 0xff; case 0x7a: /* Input Window Y End Position 1 */ return s->ix[1] >> 3; case 0x7c: /* Output Window X Start Position 0 */ return s->ox[0] & 0xff; case 0x7e: /* Output Window X Start Position 1 */ return s->ox[0] >> 3; case 0x80: /* Output Window Y Start Position 0 */ return s->oy[0] & 0xff; case 0x82: /* Output Window Y Start Position 1 */ return s->oy[0] >> 3; case 0x84: /* Output Window X End Position 0 */ return s->ox[1] & 0xff; case 0x86: /* Output Window X End Position 1 */ return s->ox[1] >> 3; case 0x88: /* Output Window Y End Position 0 */ return s->oy[1] & 0xff; case 0x8a: /* Output Window Y End Position 1 */ return s->oy[1] >> 3; case 0x8c: /* Input Data Format */ return s->iformat; case 0x8e: /* Data Source Select */ return s->source; case 0x90: /* Display Memory Data Port */ return 0; case 0xa8: /* Border Color 0 */ return s->border_r; case 0xaa: /* Border Color 1 */ return s->border_g; case 0xac: /* Border Color 2 */ return s->border_b; case 0xb4: /* Gamma Correction Enable */ return s->gamma_config; case 0xb6: /* Gamma Correction Table Index */ return s->gamma_idx; case 0xb8: /* Gamma Correction Table Data */ return s->gamma_lut[s->gamma_idx ++]; case 0xba: /* 3x3 Matrix Enable */ return s->matrix_ena; case 0xbc ... 0xde: /* Coefficient Registers */ return s->matrix_coeff[(reg - 0xbc) >> 1]; case 0xe0: /* 3x3 Matrix Red Offset */ return s->matrix_r; case 0xe2: /* 3x3 Matrix Green Offset */ return s->matrix_g; case 0xe4: /* 3x3 Matrix Blue Offset */ return s->matrix_b; case 0xe6: /* Power-save */ return s->pm; case 0xe8: /* Non-display Period Control / Status */ return s->status | (1 << 5); case 0xea: /* RGB Interface Control */ return s->rgbgpio_dir; case 0xec: /* RGB Interface Status */ return s->rgbgpio; case 0xee: /* General-purpose IO Pins Configuration */ return s->gpio_dir; case 0xf0: /* General-purpose IO Pins Status / Control */ return s->gpio; case 0xf2: /* GPIO Positive Edge Interrupt Trigger */ return s->gpio_edge[0]; case 0xf4: /* GPIO Negative Edge Interrupt Trigger */ return s->gpio_edge[1]; case 0xf6: /* GPIO Interrupt Status */ return s->gpio_irq; case 0xf8: /* GPIO Pull-down Control */ return s->gpio_pdown; default: fprintf(stderr, "%s: unknown register %02x\n", __FUNCTION__, reg); return 0; } } static void blizzard_reg_write(void *opaque, uint8_t reg, uint16_t value) { struct blizzard_s *s = (struct blizzard_s *) opaque; switch (reg) { case 0x04: /* PLL M-Divider */ s->pll = (value & 0x3f) + 1; break; case 0x06: /* PLL Lock Range Control */ s->pll_range = value & 3; break; case 0x08: /* PLL Lock Synthesis Control 0 */ s->pll_ctrl &= 0xf00; s->pll_ctrl |= (value << 0) & 0x0ff; break; case 0x0a: /* PLL Lock Synthesis Control 1 */ s->pll_ctrl &= 0x0ff; s->pll_ctrl |= (value << 8) & 0xf00; break; case 0x0c: /* PLL Mode Control 0 */ s->pll_mode = value & 0x77; if ((value & 3) == 0 || (value & 3) == 3) fprintf(stderr, "%s: wrong PLL Control bits (%i)\n", __FUNCTION__, value & 3); break; case 0x0e: /* Clock-Source Select */ s->clksel = value & 0xff; break; case 0x10: /* Memory Controller Activate */ s->memenable = value & 1; break; case 0x14: /* Memory Controller Bank 0 Status Flag */ break; case 0x18: /* Auto-Refresh Interval Setting 0 */ s->memrefresh &= 0xf00; s->memrefresh |= (value << 0) & 0x0ff; break; case 0x1a: /* Auto-Refresh Interval Setting 1 */ s->memrefresh &= 0x0ff; s->memrefresh |= (value << 8) & 0xf00; break; case 0x1c: /* Power-On Sequence Timing Control */ s->timing[0] = value & 0x7f; break; case 0x1e: /* Timing Control 0 */ s->timing[1] = value & 0x17; break; case 0x20: /* Timing Control 1 */ s->timing[2] = value & 0x35; break; case 0x24: /* Arbitration Priority Control */ s->priority = value & 1; break; case 0x28: /* LCD Panel Configuration */ s->lcd_config = value & 0xff; if (value & (1 << 7)) fprintf(stderr, "%s: data swap not supported!\n", __FUNCTION__); break; case 0x2a: /* LCD Horizontal Display Width */ s->x = value << 3; break; case 0x2c: /* LCD Horizontal Non-display Period */ s->hndp = value & 0xff; break; case 0x2e: /* LCD Vertical Display Height 0 */ s->y &= 0x300; s->y |= (value << 0) & 0x0ff; break; case 0x30: /* LCD Vertical Display Height 1 */ s->y &= 0x0ff; s->y |= (value << 8) & 0x300; break; case 0x32: /* LCD Vertical Non-display Period */ s->vndp = value & 0xff; break; case 0x34: /* LCD HS Pulse-width */ s->hsync = value & 0xff; break; case 0x36: /* LCD HS Pulse Start Position */ s->skipx = value & 0xff; break; case 0x38: /* LCD VS Pulse-width */ s->vsync = value & 0xbf; break; case 0x3a: /* LCD VS Pulse Start Position */ s->skipy = value & 0xff; break; case 0x3c: /* PCLK Polarity */ s->pclk = value & 0x82; /* Affects calculation of s->hndp, s->hsync and s->skipx. */ break; case 0x3e: /* High-speed Serial Interface Tx Configuration Port 0 */ s->hssi_config[0] = value; break; case 0x40: /* High-speed Serial Interface Tx Configuration Port 1 */ s->hssi_config[1] = value; if (((value >> 4) & 3) == 3) fprintf(stderr, "%s: Illegal active-data-links value\n", __FUNCTION__); break; case 0x42: /* High-speed Serial Interface Tx Mode */ s->hssi_config[2] = value & 0xbd; break; case 0x44: /* TV Display Configuration */ s->tv_config = value & 0xfe; break; case 0x46 ... 0x4c: /* TV Vertical Blanking Interval Data bits 0 */ s->tv_timing[(reg - 0x46) >> 1] = value; break; case 0x4e: /* VBI: Closed Caption / XDS Control / Status */ s->vbi = value; break; case 0x50: /* TV Horizontal Start Position */ s->tv_x = value; break; case 0x52: /* TV Vertical Start Position */ s->tv_y = value & 0x7f; break; case 0x54: /* TV Test Pattern Setting */ s->tv_test = value; break; case 0x56: /* TV Filter Setting */ s->tv_filter_config = value & 0xbf; break; case 0x58: /* TV Filter Coefficient Index */ s->tv_filter_idx = value & 0x1f; break; case 0x5a: /* TV Filter Coefficient Data */ if (s->tv_filter_idx < 0x20) s->tv_filter_coeff[s->tv_filter_idx ++] = value; break; case 0x60: /* Input YUV/RGB Translate Mode 0 */ s->yrc[0] = value & 0xb0; break; case 0x62: /* Input YUV/RGB Translate Mode 1 */ s->yrc[1] = value & 0x30; break; case 0x64: /* U Data Fix */ s->u = value & 0xff; break; case 0x66: /* V Data Fix */ s->v = value & 0xff; break; case 0x68: /* Display Mode */ if ((s->mode ^ value) & 3) s->invalidate = 1; s->mode = value & 0xb7; s->enable = value & 1; s->blank = (value >> 1) & 1; if (value & (1 << 4)) fprintf(stderr, "%s: Macrovision enable attempt!\n", __FUNCTION__); break; case 0x6a: /* Special Effects */ s->effect = value & 0xfb; break; case 0x6c: /* Input Window X Start Position 0 */ s->ix[0] &= 0x300; s->ix[0] |= (value << 0) & 0x0ff; break; case 0x6e: /* Input Window X Start Position 1 */ s->ix[0] &= 0x0ff; s->ix[0] |= (value << 8) & 0x300; break; case 0x70: /* Input Window Y Start Position 0 */ s->iy[0] &= 0x300; s->iy[0] |= (value << 0) & 0x0ff; break; case 0x72: /* Input Window Y Start Position 1 */ s->iy[0] &= 0x0ff; s->iy[0] |= (value << 8) & 0x300; break; case 0x74: /* Input Window X End Position 0 */ s->ix[1] &= 0x300; s->ix[1] |= (value << 0) & 0x0ff; break; case 0x76: /* Input Window X End Position 1 */ s->ix[1] &= 0x0ff; s->ix[1] |= (value << 8) & 0x300; break; case 0x78: /* Input Window Y End Position 0 */ s->iy[1] &= 0x300; s->iy[1] |= (value << 0) & 0x0ff; break; case 0x7a: /* Input Window Y End Position 1 */ s->iy[1] &= 0x0ff; s->iy[1] |= (value << 8) & 0x300; break; case 0x7c: /* Output Window X Start Position 0 */ s->ox[0] &= 0x300; s->ox[0] |= (value << 0) & 0x0ff; break; case 0x7e: /* Output Window X Start Position 1 */ s->ox[0] &= 0x0ff; s->ox[0] |= (value << 8) & 0x300; break; case 0x80: /* Output Window Y Start Position 0 */ s->oy[0] &= 0x300; s->oy[0] |= (value << 0) & 0x0ff; break; case 0x82: /* Output Window Y Start Position 1 */ s->oy[0] &= 0x0ff; s->oy[0] |= (value << 8) & 0x300; break; case 0x84: /* Output Window X End Position 0 */ s->ox[1] &= 0x300; s->ox[1] |= (value << 0) & 0x0ff; break; case 0x86: /* Output Window X End Position 1 */ s->ox[1] &= 0x0ff; s->ox[1] |= (value << 8) & 0x300; break; case 0x88: /* Output Window Y End Position 0 */ s->oy[1] &= 0x300; s->oy[1] |= (value << 0) & 0x0ff; break; case 0x8a: /* Output Window Y End Position 1 */ s->oy[1] &= 0x0ff; s->oy[1] |= (value << 8) & 0x300; break; case 0x8c: /* Input Data Format */ s->iformat = value & 0xf; s->bpp = blizzard_iformat_bpp[s->iformat]; if (!s->bpp) fprintf(stderr, "%s: Illegal or unsupported input format %x\n", __FUNCTION__, s->iformat); break; case 0x8e: /* Data Source Select */ s->source = value & 7; /* Currently all windows will be "destructive overlays". */ if ((!(s->effect & (1 << 3)) && (s->ix[0] != s->ox[0] || s->iy[0] != s->oy[0] || s->ix[1] != s->ox[1] || s->iy[1] != s->oy[1])) || !((s->ix[1] - s->ix[0]) & (s->iy[1] - s->iy[0]) & (s->ox[1] - s->ox[0]) & (s->oy[1] - s->oy[0]) & 1)) fprintf(stderr, "%s: Illegal input/output window positions\n", __FUNCTION__); blizzard_transfer_setup(s); break; case 0x90: /* Display Memory Data Port */ if (!s->data.len && !blizzard_transfer_setup(s)) break; *s->data.ptr ++ = value; if (-- s->data.len == 0) blizzard_window(s); break; case 0xa8: /* Border Color 0 */ s->border_r = value; break; case 0xaa: /* Border Color 1 */ s->border_g = value; break; case 0xac: /* Border Color 2 */ s->border_b = value; break; case 0xb4: /* Gamma Correction Enable */ s->gamma_config = value & 0x87; break; case 0xb6: /* Gamma Correction Table Index */ s->gamma_idx = value; break; case 0xb8: /* Gamma Correction Table Data */ s->gamma_lut[s->gamma_idx ++] = value; break; case 0xba: /* 3x3 Matrix Enable */ s->matrix_ena = value & 1; break; case 0xbc ... 0xde: /* Coefficient Registers */ s->matrix_coeff[(reg - 0xbc) >> 1] = value & ((reg & 2) ? 0x80 : 0xff); break; case 0xe0: /* 3x3 Matrix Red Offset */ s->matrix_r = value; break; case 0xe2: /* 3x3 Matrix Green Offset */ s->matrix_g = value; break; case 0xe4: /* 3x3 Matrix Blue Offset */ s->matrix_b = value; break; case 0xe6: /* Power-save */ s->pm = value & 0x83; if (value & s->mode & 1) fprintf(stderr, "%s: The display must be disabled before entering " "Standby Mode\n", __FUNCTION__); break; case 0xe8: /* Non-display Period Control / Status */ s->status = value & 0x1b; break; case 0xea: /* RGB Interface Control */ s->rgbgpio_dir = value & 0x8f; break; case 0xec: /* RGB Interface Status */ s->rgbgpio = value & 0xcf; break; case 0xee: /* General-purpose IO Pins Configuration */ s->gpio_dir = value; break; case 0xf0: /* General-purpose IO Pins Status / Control */ s->gpio = value; break; case 0xf2: /* GPIO Positive Edge Interrupt Trigger */ s->gpio_edge[0] = value; break; case 0xf4: /* GPIO Negative Edge Interrupt Trigger */ s->gpio_edge[1] = value; break; case 0xf6: /* GPIO Interrupt Status */ s->gpio_irq &= value; break; case 0xf8: /* GPIO Pull-down Control */ s->gpio_pdown = value; break; default: fprintf(stderr, "%s: unknown register %02x\n", __FUNCTION__, reg); break; } } uint16_t s1d13745_read(void *opaque, int dc) { struct blizzard_s *s = (struct blizzard_s *) opaque; uint16_t value = blizzard_reg_read(s, s->reg); if (s->swallow -- > 0) return 0; if (dc) s->reg ++; return value; } void s1d13745_write(void *opaque, int dc, uint16_t value) { struct blizzard_s *s = (struct blizzard_s *) opaque; if (s->swallow -- > 0) return; if (dc) { blizzard_reg_write(s, s->reg, value); if (s->reg != 0x90 && s->reg != 0x5a && s->reg != 0xb8) s->reg += 2; } else s->reg = value & 0xff; } void s1d13745_write_block(void *opaque, int dc, void *buf, size_t len, int pitch) { struct blizzard_s *s = (struct blizzard_s *) opaque; while (len > 0) { if (s->reg == 0x90 && dc && (s->data.len || blizzard_transfer_setup(s)) && len >= (s->data.len << 1)) { len -= s->data.len << 1; s->data.len = 0; s->data.data = buf; if (pitch) s->data.pitch = pitch; blizzard_window(s); s->data.data = s->data.buf; continue; } s1d13745_write(opaque, dc, *(uint16_t *) buf); len -= 2; buf += 2; } return; } static void blizzard_update_display(void *opaque) { struct blizzard_s *s = (struct blizzard_s *) opaque; int y, bypp, bypl, bwidth; uint8_t *src, *dst; if (!s->enable) return; if (s->x != ds_get_width(s->state) || s->y != ds_get_height(s->state)) { s->invalidate = 1; qemu_console_resize(s->state, s->x, s->y); } if (s->invalidate) { s->invalidate = 0; if (s->blank) { bypp = (ds_get_bits_per_pixel(s->state) + 7) >> 3; memset(ds_get_data(s->state), 0, bypp * s->x * s->y); return; } s->mx[0] = 0; s->mx[1] = s->x; s->my[0] = 0; s->my[1] = s->y; } if (s->mx[1] <= s->mx[0]) return; bypp = (ds_get_bits_per_pixel(s->state) + 7) >> 3; bypl = bypp * s->x; bwidth = bypp * (s->mx[1] - s->mx[0]); y = s->my[0]; src = s->fb + bypl * y + bypp * s->mx[0]; dst = ds_get_data(s->state) + bypl * y + bypp * s->mx[0]; for (; y < s->my[1]; y ++, src += bypl, dst += bypl) memcpy(dst, src, bwidth); dpy_update(s->state, s->mx[0], s->my[0], s->mx[1] - s->mx[0], y - s->my[0]); s->mx[0] = s->x; s->mx[1] = 0; s->my[0] = s->y; s->my[1] = 0; } static void blizzard_screen_dump(void *opaque, const char *filename) { struct blizzard_s *s = (struct blizzard_s *) opaque; blizzard_update_display(opaque); if (s && ds_get_data(s->state)) ppm_save(filename, ds_get_data(s->state), s->x, s->y, ds_get_linesize(s->state)); } #define DEPTH 8 #include "blizzard_template.h" #define DEPTH 15 #include "blizzard_template.h" #define DEPTH 16 #include "blizzard_template.h" #define DEPTH 24 #include "blizzard_template.h" #define DEPTH 32 #include "blizzard_template.h" void *s1d13745_init(qemu_irq gpio_int) { struct blizzard_s *s = (struct blizzard_s *) qemu_mallocz(sizeof(*s)); s->fb = qemu_malloc(0x180000); switch (ds_get_bits_per_pixel(s->state)) { case 0: s->line_fn_tab[0] = s->line_fn_tab[1] = qemu_mallocz(sizeof(blizzard_fn_t) * 0x10); break; case 8: s->line_fn_tab[0] = blizzard_draw_fn_8; s->line_fn_tab[1] = blizzard_draw_fn_r_8; break; case 15: s->line_fn_tab[0] = blizzard_draw_fn_15; s->line_fn_tab[1] = blizzard_draw_fn_r_15; break; case 16: s->line_fn_tab[0] = blizzard_draw_fn_16; s->line_fn_tab[1] = blizzard_draw_fn_r_16; break; case 24: s->line_fn_tab[0] = blizzard_draw_fn_24; s->line_fn_tab[1] = blizzard_draw_fn_r_24; break; case 32: s->line_fn_tab[0] = blizzard_draw_fn_32; s->line_fn_tab[1] = blizzard_draw_fn_r_32; break; default: fprintf(stderr, "%s: Bad color depth\n", __FUNCTION__); exit(1); } blizzard_reset(s); s->state = graphic_console_init(blizzard_update_display, blizzard_invalidate_display, blizzard_screen_dump, NULL, s); return s; }