/* * Intel XScale PXA255/270 LCDC emulation. * * Copyright (c) 2006 Openedhand Ltd. * Written by Andrzej Zaborowski * * This code is licensed under the GPLv2. */ #include "vl.h" typedef void (*drawfn)(uint32_t *, uint8_t *, const uint8_t *, int, int); struct pxa2xx_lcdc_s { target_phys_addr_t base; qemu_irq irq; int irqlevel; int invalidated; DisplayState *ds; drawfn *line_fn[2]; int dest_width; int xres, yres; int pal_for; int transp; enum { pxa_lcdc_2bpp = 1, pxa_lcdc_4bpp = 2, pxa_lcdc_8bpp = 3, pxa_lcdc_16bpp = 4, pxa_lcdc_18bpp = 5, pxa_lcdc_18pbpp = 6, pxa_lcdc_19bpp = 7, pxa_lcdc_19pbpp = 8, pxa_lcdc_24bpp = 9, pxa_lcdc_25bpp = 10, } bpp; uint32_t control[6]; uint32_t status[2]; uint32_t ovl1c[2]; uint32_t ovl2c[2]; uint32_t ccr; uint32_t cmdcr; uint32_t trgbr; uint32_t tcr; uint32_t liidr; uint8_t bscntr; struct { target_phys_addr_t branch; int up; uint8_t palette[1024]; uint8_t pbuffer[1024]; void (*redraw)(struct pxa2xx_lcdc_s *s, uint8_t *fb, int *miny, int *maxy); target_phys_addr_t descriptor; target_phys_addr_t source; uint32_t id; uint32_t command; } dma_ch[7]; void (*vsync_cb)(void *opaque); void *opaque; int orientation; }; struct __attribute__ ((__packed__)) pxa_frame_descriptor_s { uint32_t fdaddr; uint32_t fsaddr; uint32_t fidr; uint32_t ldcmd; }; #define LCCR0 0x000 /* LCD Controller Control register 0 */ #define LCCR1 0x004 /* LCD Controller Control register 1 */ #define LCCR2 0x008 /* LCD Controller Control register 2 */ #define LCCR3 0x00c /* LCD Controller Control register 3 */ #define LCCR4 0x010 /* LCD Controller Control register 4 */ #define LCCR5 0x014 /* LCD Controller Control register 5 */ #define FBR0 0x020 /* DMA Channel 0 Frame Branch register */ #define FBR1 0x024 /* DMA Channel 1 Frame Branch register */ #define FBR2 0x028 /* DMA Channel 2 Frame Branch register */ #define FBR3 0x02c /* DMA Channel 3 Frame Branch register */ #define FBR4 0x030 /* DMA Channel 4 Frame Branch register */ #define FBR5 0x110 /* DMA Channel 5 Frame Branch register */ #define FBR6 0x114 /* DMA Channel 6 Frame Branch register */ #define LCSR1 0x034 /* LCD Controller Status register 1 */ #define LCSR0 0x038 /* LCD Controller Status register 0 */ #define LIIDR 0x03c /* LCD Controller Interrupt ID register */ #define TRGBR 0x040 /* TMED RGB Seed register */ #define TCR 0x044 /* TMED Control register */ #define OVL1C1 0x050 /* Overlay 1 Control register 1 */ #define OVL1C2 0x060 /* Overlay 1 Control register 2 */ #define OVL2C1 0x070 /* Overlay 2 Control register 1 */ #define OVL2C2 0x080 /* Overlay 2 Control register 2 */ #define CCR 0x090 /* Cursor Control register */ #define CMDCR 0x100 /* Command Control register */ #define PRSR 0x104 /* Panel Read Status register */ #define PXA_LCDDMA_CHANS 7 #define DMA_FDADR 0x00 /* Frame Descriptor Address register */ #define DMA_FSADR 0x04 /* Frame Source Address register */ #define DMA_FIDR 0x08 /* Frame ID register */ #define DMA_LDCMD 0x0c /* Command register */ /* LCD Buffer Strength Control register */ #define BSCNTR 0x04000054 /* Bitfield masks */ #define LCCR0_ENB (1 << 0) #define LCCR0_CMS (1 << 1) #define LCCR0_SDS (1 << 2) #define LCCR0_LDM (1 << 3) #define LCCR0_SOFM0 (1 << 4) #define LCCR0_IUM (1 << 5) #define LCCR0_EOFM0 (1 << 6) #define LCCR0_PAS (1 << 7) #define LCCR0_DPD (1 << 9) #define LCCR0_DIS (1 << 10) #define LCCR0_QDM (1 << 11) #define LCCR0_PDD (0xff << 12) #define LCCR0_BSM0 (1 << 20) #define LCCR0_OUM (1 << 21) #define LCCR0_LCDT (1 << 22) #define LCCR0_RDSTM (1 << 23) #define LCCR0_CMDIM (1 << 24) #define LCCR0_OUC (1 << 25) #define LCCR0_LDDALT (1 << 26) #define LCCR1_PPL(x) ((x) & 0x3ff) #define LCCR2_LPP(x) ((x) & 0x3ff) #define LCCR3_API (15 << 16) #define LCCR3_BPP(x) ((((x) >> 24) & 7) | (((x) >> 26) & 8)) #define LCCR3_PDFOR(x) (((x) >> 30) & 3) #define LCCR4_K1(x) (((x) >> 0) & 7) #define LCCR4_K2(x) (((x) >> 3) & 7) #define LCCR4_K3(x) (((x) >> 6) & 7) #define LCCR4_PALFOR(x) (((x) >> 15) & 3) #define LCCR5_SOFM(ch) (1 << (ch - 1)) #define LCCR5_EOFM(ch) (1 << (ch + 7)) #define LCCR5_BSM(ch) (1 << (ch + 15)) #define LCCR5_IUM(ch) (1 << (ch + 23)) #define OVLC1_EN (1 << 31) #define CCR_CEN (1 << 31) #define FBR_BRA (1 << 0) #define FBR_BINT (1 << 1) #define FBR_SRCADDR (0xfffffff << 4) #define LCSR0_LDD (1 << 0) #define LCSR0_SOF0 (1 << 1) #define LCSR0_BER (1 << 2) #define LCSR0_ABC (1 << 3) #define LCSR0_IU0 (1 << 4) #define LCSR0_IU1 (1 << 5) #define LCSR0_OU (1 << 6) #define LCSR0_QD (1 << 7) #define LCSR0_EOF0 (1 << 8) #define LCSR0_BS0 (1 << 9) #define LCSR0_SINT (1 << 10) #define LCSR0_RDST (1 << 11) #define LCSR0_CMDINT (1 << 12) #define LCSR0_BERCH(x) (((x) & 7) << 28) #define LCSR1_SOF(ch) (1 << (ch - 1)) #define LCSR1_EOF(ch) (1 << (ch + 7)) #define LCSR1_BS(ch) (1 << (ch + 15)) #define LCSR1_IU(ch) (1 << (ch + 23)) #define LDCMD_LENGTH(x) ((x) & 0x001ffffc) #define LDCMD_EOFINT (1 << 21) #define LDCMD_SOFINT (1 << 22) #define LDCMD_PAL (1 << 26) /* Route internal interrupt lines to the global IC */ static void pxa2xx_lcdc_int_update(struct pxa2xx_lcdc_s *s) { int level = 0; level |= (s->status[0] & LCSR0_LDD) && !(s->control[0] & LCCR0_LDM); level |= (s->status[0] & LCSR0_SOF0) && !(s->control[0] & LCCR0_SOFM0); level |= (s->status[0] & LCSR0_IU0) && !(s->control[0] & LCCR0_IUM); level |= (s->status[0] & LCSR0_IU1) && !(s->control[5] & LCCR5_IUM(1)); level |= (s->status[0] & LCSR0_OU) && !(s->control[0] & LCCR0_OUM); level |= (s->status[0] & LCSR0_QD) && !(s->control[0] & LCCR0_QDM); level |= (s->status[0] & LCSR0_EOF0) && !(s->control[0] & LCCR0_EOFM0); level |= (s->status[0] & LCSR0_BS0) && !(s->control[0] & LCCR0_BSM0); level |= (s->status[0] & LCSR0_RDST) && !(s->control[0] & LCCR0_RDSTM); level |= (s->status[0] & LCSR0_CMDINT) && !(s->control[0] & LCCR0_CMDIM); level |= (s->status[1] & ~s->control[5]); qemu_set_irq(s->irq, !!level); s->irqlevel = level; } /* Set Branch Status interrupt high and poke associated registers */ static inline void pxa2xx_dma_bs_set(struct pxa2xx_lcdc_s *s, int ch) { int unmasked; if (ch == 0) { s->status[0] |= LCSR0_BS0; unmasked = !(s->control[0] & LCCR0_BSM0); } else { s->status[1] |= LCSR1_BS(ch); unmasked = !(s->control[5] & LCCR5_BSM(ch)); } if (unmasked) { if (s->irqlevel) s->status[0] |= LCSR0_SINT; else s->liidr = s->dma_ch[ch].id; } } /* Set Start Of Frame Status interrupt high and poke associated registers */ static inline void pxa2xx_dma_sof_set(struct pxa2xx_lcdc_s *s, int ch) { int unmasked; if (!(s->dma_ch[ch].command & LDCMD_SOFINT)) return; if (ch == 0) { s->status[0] |= LCSR0_SOF0; unmasked = !(s->control[0] & LCCR0_SOFM0); } else { s->status[1] |= LCSR1_SOF(ch); unmasked = !(s->control[5] & LCCR5_SOFM(ch)); } if (unmasked) { if (s->irqlevel) s->status[0] |= LCSR0_SINT; else s->liidr = s->dma_ch[ch].id; } } /* Set End Of Frame Status interrupt high and poke associated registers */ static inline void pxa2xx_dma_eof_set(struct pxa2xx_lcdc_s *s, int ch) { int unmasked; if (!(s->dma_ch[ch].command & LDCMD_EOFINT)) return; if (ch == 0) { s->status[0] |= LCSR0_EOF0; unmasked = !(s->control[0] & LCCR0_EOFM0); } else { s->status[1] |= LCSR1_EOF(ch); unmasked = !(s->control[5] & LCCR5_EOFM(ch)); } if (unmasked) { if (s->irqlevel) s->status[0] |= LCSR0_SINT; else s->liidr = s->dma_ch[ch].id; } } /* Set Bus Error Status interrupt high and poke associated registers */ static inline void pxa2xx_dma_ber_set(struct pxa2xx_lcdc_s *s, int ch) { s->status[0] |= LCSR0_BERCH(ch) | LCSR0_BER; if (s->irqlevel) s->status[0] |= LCSR0_SINT; else s->liidr = s->dma_ch[ch].id; } /* Set Read Status interrupt high and poke associated registers */ static inline void pxa2xx_dma_rdst_set(struct pxa2xx_lcdc_s *s) { s->status[0] |= LCSR0_RDST; if (s->irqlevel && !(s->control[0] & LCCR0_RDSTM)) s->status[0] |= LCSR0_SINT; } /* Load new Frame Descriptors from DMA */ static void pxa2xx_descriptor_load(struct pxa2xx_lcdc_s *s) { struct pxa_frame_descriptor_s *desc[PXA_LCDDMA_CHANS]; target_phys_addr_t descptr; int i; for (i = 0; i < PXA_LCDDMA_CHANS; i ++) { desc[i] = 0; s->dma_ch[i].source = 0; if (!s->dma_ch[i].up) continue; if (s->dma_ch[i].branch & FBR_BRA) { descptr = s->dma_ch[i].branch & FBR_SRCADDR; if (s->dma_ch[i].branch & FBR_BINT) pxa2xx_dma_bs_set(s, i); s->dma_ch[i].branch &= ~FBR_BRA; } else descptr = s->dma_ch[i].descriptor; if (!(descptr >= PXA2XX_RAM_BASE && descptr + sizeof(*desc[i]) <= PXA2XX_RAM_BASE + phys_ram_size)) continue; descptr -= PXA2XX_RAM_BASE; desc[i] = (struct pxa_frame_descriptor_s *) (phys_ram_base + descptr); s->dma_ch[i].descriptor = desc[i]->fdaddr; s->dma_ch[i].source = desc[i]->fsaddr; s->dma_ch[i].id = desc[i]->fidr; s->dma_ch[i].command = desc[i]->ldcmd; } } static uint32_t pxa2xx_lcdc_read(void *opaque, target_phys_addr_t offset) { struct pxa2xx_lcdc_s *s = (struct pxa2xx_lcdc_s *) opaque; int ch; offset -= s->base; switch (offset) { case LCCR0: return s->control[0]; case LCCR1: return s->control[1]; case LCCR2: return s->control[2]; case LCCR3: return s->control[3]; case LCCR4: return s->control[4]; case LCCR5: return s->control[5]; case OVL1C1: return s->ovl1c[0]; case OVL1C2: return s->ovl1c[1]; case OVL2C1: return s->ovl2c[0]; case OVL2C2: return s->ovl2c[1]; case CCR: return s->ccr; case CMDCR: return s->cmdcr; case TRGBR: return s->trgbr; case TCR: return s->tcr; case 0x200 ... 0x1000: /* DMA per-channel registers */ ch = (offset - 0x200) >> 4; if (!(ch >= 0 && ch < PXA_LCDDMA_CHANS)) goto fail; switch (offset & 0xf) { case DMA_FDADR: return s->dma_ch[ch].descriptor; case DMA_FSADR: return s->dma_ch[ch].source; case DMA_FIDR: return s->dma_ch[ch].id; case DMA_LDCMD: return s->dma_ch[ch].command; default: goto fail; } case FBR0: return s->dma_ch[0].branch; case FBR1: return s->dma_ch[1].branch; case FBR2: return s->dma_ch[2].branch; case FBR3: return s->dma_ch[3].branch; case FBR4: return s->dma_ch[4].branch; case FBR5: return s->dma_ch[5].branch; case FBR6: return s->dma_ch[6].branch; case BSCNTR: return s->bscntr; case PRSR: return 0; case LCSR0: return s->status[0]; case LCSR1: return s->status[1]; case LIIDR: return s->liidr; default: fail: cpu_abort(cpu_single_env, "%s: Bad offset " REG_FMT "\n", __FUNCTION__, offset); } return 0; } static void pxa2xx_lcdc_write(void *opaque, target_phys_addr_t offset, uint32_t value) { struct pxa2xx_lcdc_s *s = (struct pxa2xx_lcdc_s *) opaque; int ch; offset -= s->base; switch (offset) { case LCCR0: /* ACK Quick Disable done */ if ((s->control[0] & LCCR0_ENB) && !(value & LCCR0_ENB)) s->status[0] |= LCSR0_QD; if (!(s->control[0] & LCCR0_LCDT) && (value & LCCR0_LCDT)) printf("%s: internal frame buffer unsupported\n", __FUNCTION__); if ((s->control[3] & LCCR3_API) && (value & LCCR0_ENB) && !(value & LCCR0_LCDT)) s->status[0] |= LCSR0_ABC; s->control[0] = value & 0x07ffffff; pxa2xx_lcdc_int_update(s); s->dma_ch[0].up = !!(value & LCCR0_ENB); s->dma_ch[1].up = (s->ovl1c[0] & OVLC1_EN) || (value & LCCR0_SDS); break; case LCCR1: s->control[1] = value; break; case LCCR2: s->control[2] = value; break; case LCCR3: s->control[3] = value & 0xefffffff; s->bpp = LCCR3_BPP(value); break; case LCCR4: s->control[4] = value & 0x83ff81ff; break; case LCCR5: s->control[5] = value & 0x3f3f3f3f; break; case OVL1C1: if (!(s->ovl1c[0] & OVLC1_EN) && (value & OVLC1_EN)) printf("%s: Overlay 1 not supported\n", __FUNCTION__); s->ovl1c[0] = value & 0x80ffffff; s->dma_ch[1].up = (value & OVLC1_EN) || (s->control[0] & LCCR0_SDS); break; case OVL1C2: s->ovl1c[1] = value & 0x000fffff; break; case OVL2C1: if (!(s->ovl2c[0] & OVLC1_EN) && (value & OVLC1_EN)) printf("%s: Overlay 2 not supported\n", __FUNCTION__); s->ovl2c[0] = value & 0x80ffffff; s->dma_ch[2].up = !!(value & OVLC1_EN); s->dma_ch[3].up = !!(value & OVLC1_EN); s->dma_ch[4].up = !!(value & OVLC1_EN); break; case OVL2C2: s->ovl2c[1] = value & 0x007fffff; break; case CCR: if (!(s->ccr & CCR_CEN) && (value & CCR_CEN)) printf("%s: Hardware cursor unimplemented\n", __FUNCTION__); s->ccr = value & 0x81ffffe7; s->dma_ch[5].up = !!(value & CCR_CEN); break; case CMDCR: s->cmdcr = value & 0xff; break; case TRGBR: s->trgbr = value & 0x00ffffff; break; case TCR: s->tcr = value & 0x7fff; break; case 0x200 ... 0x1000: /* DMA per-channel registers */ ch = (offset - 0x200) >> 4; if (!(ch >= 0 && ch < PXA_LCDDMA_CHANS)) goto fail; switch (offset & 0xf) { case DMA_FDADR: s->dma_ch[ch].descriptor = value & 0xfffffff0; break; default: goto fail; } break; case FBR0: s->dma_ch[0].branch = value & 0xfffffff3; break; case FBR1: s->dma_ch[1].branch = value & 0xfffffff3; break; case FBR2: s->dma_ch[2].branch = value & 0xfffffff3; break; case FBR3: s->dma_ch[3].branch = value & 0xfffffff3; break; case FBR4: s->dma_ch[4].branch = value & 0xfffffff3; break; case FBR5: s->dma_ch[5].branch = value & 0xfffffff3; break; case FBR6: s->dma_ch[6].branch = value & 0xfffffff3; break; case BSCNTR: s->bscntr = value & 0xf; break; case PRSR: break; case LCSR0: s->status[0] &= ~(value & 0xfff); if (value & LCSR0_BER) s->status[0] &= ~LCSR0_BERCH(7); break; case LCSR1: s->status[1] &= ~(value & 0x3e3f3f); break; default: fail: cpu_abort(cpu_single_env, "%s: Bad offset " REG_FMT "\n", __FUNCTION__, offset); } } static CPUReadMemoryFunc *pxa2xx_lcdc_readfn[] = { pxa2xx_lcdc_read, pxa2xx_lcdc_read, pxa2xx_lcdc_read }; static CPUWriteMemoryFunc *pxa2xx_lcdc_writefn[] = { pxa2xx_lcdc_write, pxa2xx_lcdc_write, pxa2xx_lcdc_write }; static inline uint32_t rgb_to_pixel8(unsigned int r, unsigned int g, unsigned b) { return ((r >> 5) << 5) | ((g >> 5) << 2) | (b >> 6); } static inline uint32_t rgb_to_pixel15(unsigned int r, unsigned int g, unsigned b) { return ((r >> 3) << 10) | ((g >> 3) << 5) | (b >> 3); } static inline uint32_t rgb_to_pixel16(unsigned int r, unsigned int g, unsigned b) { return ((r >> 3) << 11) | ((g >> 2) << 5) | (b >> 3); } static inline uint32_t rgb_to_pixel24(unsigned int r, unsigned int g, unsigned b) { return (r << 16) | (g << 8) | b; } static inline uint32_t rgb_to_pixel32(unsigned int r, unsigned int g, unsigned b) { return (r << 16) | (g << 8) | b; } /* Load new palette for a given DMA channel, convert to internal format */ static void pxa2xx_palette_parse(struct pxa2xx_lcdc_s *s, int ch, int bpp) { int i, n, format, r, g, b, alpha; uint32_t *dest, *src; s->pal_for = LCCR4_PALFOR(s->control[4]); format = s->pal_for; switch (bpp) { case pxa_lcdc_2bpp: n = 4; break; case pxa_lcdc_4bpp: n = 16; break; case pxa_lcdc_8bpp: n = 256; break; default: format = 0; return; } src = (uint32_t *) s->dma_ch[ch].pbuffer; dest = (uint32_t *) s->dma_ch[ch].palette; alpha = r = g = b = 0; for (i = 0; i < n; i ++) { switch (format) { case 0: /* 16 bpp, no transparency */ alpha = 0; if (s->control[0] & LCCR0_CMS) r = g = b = *src & 0xff; else { r = (*src & 0xf800) >> 8; g = (*src & 0x07e0) >> 3; b = (*src & 0x001f) << 3; } break; case 1: /* 16 bpp plus transparency */ alpha = *src & (1 << 24); if (s->control[0] & LCCR0_CMS) r = g = b = *src & 0xff; else { r = (*src & 0xf800) >> 8; g = (*src & 0x07e0) >> 3; b = (*src & 0x001f) << 3; } break; case 2: /* 18 bpp plus transparency */ alpha = *src & (1 << 24); if (s->control[0] & LCCR0_CMS) r = g = b = *src & 0xff; else { r = (*src & 0xf80000) >> 16; g = (*src & 0x00fc00) >> 8; b = (*src & 0x0000f8); } break; case 3: /* 24 bpp plus transparency */ alpha = *src & (1 << 24); if (s->control[0] & LCCR0_CMS) r = g = b = *src & 0xff; else { r = (*src & 0xff0000) >> 16; g = (*src & 0x00ff00) >> 8; b = (*src & 0x0000ff); } break; } switch (s->ds->depth) { case 8: *dest = rgb_to_pixel8(r, g, b) | alpha; break; case 15: *dest = rgb_to_pixel15(r, g, b) | alpha; break; case 16: *dest = rgb_to_pixel16(r, g, b) | alpha; break; case 24: *dest = rgb_to_pixel24(r, g, b) | alpha; break; case 32: *dest = rgb_to_pixel32(r, g, b) | alpha; break; } src ++; dest ++; } } static void pxa2xx_lcdc_dma0_redraw_horiz(struct pxa2xx_lcdc_s *s, uint8_t *fb, int *miny, int *maxy) { int y, src_width, dest_width, dirty[2]; uint8_t *src, *dest; ram_addr_t x, addr, new_addr, start, end; drawfn fn = 0; if (s->dest_width) fn = s->line_fn[s->transp][s->bpp]; if (!fn) return; src = fb; src_width = (s->xres + 3) & ~3; /* Pad to a 4 pixels multiple */ if (s->bpp == pxa_lcdc_19pbpp || s->bpp == pxa_lcdc_18pbpp) src_width *= 3; else if (s->bpp > pxa_lcdc_16bpp) src_width *= 4; else if (s->bpp > pxa_lcdc_8bpp) src_width *= 2; dest = s->ds->data; dest_width = s->xres * s->dest_width; addr = (ram_addr_t) (fb - phys_ram_base); start = addr + s->yres * src_width; end = addr; dirty[0] = dirty[1] = cpu_physical_memory_get_dirty(start, VGA_DIRTY_FLAG); for (y = 0; y < s->yres; y ++) { new_addr = addr + src_width; for (x = addr + TARGET_PAGE_SIZE; x < new_addr; x += TARGET_PAGE_SIZE) { dirty[1] = cpu_physical_memory_get_dirty(x, VGA_DIRTY_FLAG); dirty[0] |= dirty[1]; } if (dirty[0] || s->invalidated) { fn((uint32_t *) s->dma_ch[0].palette, dest, src, s->xres, s->dest_width); if (addr < start) start = addr; if (new_addr > end) end = new_addr; if (y < *miny) *miny = y; if (y >= *maxy) *maxy = y + 1; } addr = new_addr; dirty[0] = dirty[1]; src += src_width; dest += dest_width; } if (end > start) cpu_physical_memory_reset_dirty(start, end, VGA_DIRTY_FLAG); } static void pxa2xx_lcdc_dma0_redraw_vert(struct pxa2xx_lcdc_s *s, uint8_t *fb, int *miny, int *maxy) { int y, src_width, dest_width, dirty[2]; uint8_t *src, *dest; ram_addr_t x, addr, new_addr, start, end; drawfn fn = 0; if (s->dest_width) fn = s->line_fn[s->transp][s->bpp]; if (!fn) return; src = fb; src_width = (s->xres + 3) & ~3; /* Pad to a 4 pixels multiple */ if (s->bpp == pxa_lcdc_19pbpp || s->bpp == pxa_lcdc_18pbpp) src_width *= 3; else if (s->bpp > pxa_lcdc_16bpp) src_width *= 4; else if (s->bpp > pxa_lcdc_8bpp) src_width *= 2; dest_width = s->yres * s->dest_width; dest = s->ds->data + dest_width * (s->xres - 1); addr = (ram_addr_t) (fb - phys_ram_base); start = addr + s->yres * src_width; end = addr; dirty[0] = dirty[1] = cpu_physical_memory_get_dirty(start, VGA_DIRTY_FLAG); for (y = 0; y < s->yres; y ++) { new_addr = addr + src_width; for (x = addr + TARGET_PAGE_SIZE; x < new_addr; x += TARGET_PAGE_SIZE) { dirty[1] = cpu_physical_memory_get_dirty(x, VGA_DIRTY_FLAG); dirty[0] |= dirty[1]; } if (dirty[0] || s->invalidated) { fn((uint32_t *) s->dma_ch[0].palette, dest, src, s->xres, -dest_width); if (addr < start) start = addr; if (new_addr > end) end = new_addr; if (y < *miny) *miny = y; if (y >= *maxy) *maxy = y + 1; } addr = new_addr; dirty[0] = dirty[1]; src += src_width; dest += s->dest_width; } if (end > start) cpu_physical_memory_reset_dirty(start, end, VGA_DIRTY_FLAG); } static void pxa2xx_lcdc_resize(struct pxa2xx_lcdc_s *s) { int width, height; if (!(s->control[0] & LCCR0_ENB)) return; width = LCCR1_PPL(s->control[1]) + 1; height = LCCR2_LPP(s->control[2]) + 1; if (width != s->xres || height != s->yres) { if (s->orientation) dpy_resize(s->ds, height, width); else dpy_resize(s->ds, width, height); s->invalidated = 1; s->xres = width; s->yres = height; } } static void pxa2xx_update_display(void *opaque) { struct pxa2xx_lcdc_s *s = (struct pxa2xx_lcdc_s *) opaque; uint8_t *fb; target_phys_addr_t fbptr; int miny, maxy; int ch; if (!(s->control[0] & LCCR0_ENB)) return; pxa2xx_descriptor_load(s); pxa2xx_lcdc_resize(s); miny = s->yres; maxy = 0; s->transp = s->dma_ch[2].up || s->dma_ch[3].up; /* Note: With overlay planes the order depends on LCCR0 bit 25. */ for (ch = 0; ch < PXA_LCDDMA_CHANS; ch ++) if (s->dma_ch[ch].up) { if (!s->dma_ch[ch].source) { pxa2xx_dma_ber_set(s, ch); continue; } fbptr = s->dma_ch[ch].source; if (!(fbptr >= PXA2XX_RAM_BASE && fbptr <= PXA2XX_RAM_BASE + phys_ram_size)) { pxa2xx_dma_ber_set(s, ch); continue; } fbptr -= PXA2XX_RAM_BASE; fb = phys_ram_base + fbptr; if (s->dma_ch[ch].command & LDCMD_PAL) { memcpy(s->dma_ch[ch].pbuffer, fb, MAX(LDCMD_LENGTH(s->dma_ch[ch].command), sizeof(s->dma_ch[ch].pbuffer))); pxa2xx_palette_parse(s, ch, s->bpp); } else { /* Do we need to reparse palette */ if (LCCR4_PALFOR(s->control[4]) != s->pal_for) pxa2xx_palette_parse(s, ch, s->bpp); /* ACK frame start */ pxa2xx_dma_sof_set(s, ch); s->dma_ch[ch].redraw(s, fb, &miny, &maxy); s->invalidated = 0; /* ACK frame completed */ pxa2xx_dma_eof_set(s, ch); } } if (s->control[0] & LCCR0_DIS) { /* ACK last frame completed */ s->control[0] &= ~LCCR0_ENB; s->status[0] |= LCSR0_LDD; } if (s->orientation) dpy_update(s->ds, miny, 0, maxy, s->xres); else dpy_update(s->ds, 0, miny, s->xres, maxy); pxa2xx_lcdc_int_update(s); if (s->vsync_cb) s->vsync_cb(s->opaque); } static void pxa2xx_invalidate_display(void *opaque) { struct pxa2xx_lcdc_s *s = (struct pxa2xx_lcdc_s *) opaque; s->invalidated = 1; } static void pxa2xx_screen_dump(void *opaque, const char *filename) { /* TODO */ } void pxa2xx_lcdc_orientation(void *opaque, int angle) { struct pxa2xx_lcdc_s *s = (struct pxa2xx_lcdc_s *) opaque; if (angle) { s->dma_ch[0].redraw = pxa2xx_lcdc_dma0_redraw_vert; } else { s->dma_ch[0].redraw = pxa2xx_lcdc_dma0_redraw_horiz; } s->orientation = angle; s->xres = s->yres = -1; pxa2xx_lcdc_resize(s); } #define BITS 8 #include "pxa2xx_template.h" #define BITS 15 #include "pxa2xx_template.h" #define BITS 16 #include "pxa2xx_template.h" #define BITS 24 #include "pxa2xx_template.h" #define BITS 32 #include "pxa2xx_template.h" struct pxa2xx_lcdc_s *pxa2xx_lcdc_init(target_phys_addr_t base, qemu_irq irq, DisplayState *ds) { int iomemtype; struct pxa2xx_lcdc_s *s; s = (struct pxa2xx_lcdc_s *) qemu_mallocz(sizeof(struct pxa2xx_lcdc_s)); s->base = base; s->invalidated = 1; s->irq = irq; s->ds = ds; pxa2xx_lcdc_orientation(s, graphic_rotate); iomemtype = cpu_register_io_memory(0, pxa2xx_lcdc_readfn, pxa2xx_lcdc_writefn, s); cpu_register_physical_memory(base, 0x000fffff, iomemtype); graphic_console_init(ds, pxa2xx_update_display, pxa2xx_invalidate_display, pxa2xx_screen_dump, s); switch (s->ds->depth) { case 0: s->dest_width = 0; break; case 8: s->line_fn[0] = pxa2xx_draw_fn_8; s->line_fn[1] = pxa2xx_draw_fn_8t; s->dest_width = 1; break; case 15: s->line_fn[0] = pxa2xx_draw_fn_15; s->line_fn[1] = pxa2xx_draw_fn_15t; s->dest_width = 2; break; case 16: s->line_fn[0] = pxa2xx_draw_fn_16; s->line_fn[1] = pxa2xx_draw_fn_16t; s->dest_width = 2; break; case 24: s->line_fn[0] = pxa2xx_draw_fn_24; s->line_fn[1] = pxa2xx_draw_fn_24t; s->dest_width = 3; break; case 32: s->line_fn[0] = pxa2xx_draw_fn_32; s->line_fn[1] = pxa2xx_draw_fn_32t; s->dest_width = 4; break; default: fprintf(stderr, "%s: Bad color depth\n", __FUNCTION__); exit(1); } return s; } void pxa2xx_lcd_vsync_cb(struct pxa2xx_lcdc_s *s, void (*cb)(void *opaque), void *opaque) { s->vsync_cb = cb; s->opaque = opaque; }