/* * Copyright (c) 2006 Advanced Micro Devices, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. * * Neither the name of the Advanced Micro Devices, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. */ /* * Cimarron graphics processor routines. These routines program the graphics * hardware using the graphics command buffer. */ /*---------------------*/ /* CIMARRON GP GLOBALS */ /*---------------------*/ CIMARRON_STATIC unsigned long gp3_bpp = 0; CIMARRON_STATIC unsigned long gp3_ch3_bpp = 0; CIMARRON_STATIC unsigned long gp3_pat_origin = 0; CIMARRON_STATIC unsigned long gp3_buffer_lead = 0; CIMARRON_STATIC unsigned long gp3_cmd_header; CIMARRON_STATIC unsigned long gp3_cmd_top; CIMARRON_STATIC unsigned long gp3_cmd_bottom; CIMARRON_STATIC unsigned long gp3_cmd_current; CIMARRON_STATIC unsigned long gp3_cmd_next; CIMARRON_STATIC unsigned long gp3_blt_mode; CIMARRON_STATIC unsigned long gp3_vec_mode; CIMARRON_STATIC unsigned long gp3_raster_mode; CIMARRON_STATIC unsigned long gp3_pix_shift; CIMARRON_STATIC unsigned long gp3_ch3_pat; CIMARRON_STATIC unsigned long gp3_blt; CIMARRON_STATIC unsigned long gp3_blt_flags; CIMARRON_STATIC unsigned long gp3_src_stride; CIMARRON_STATIC unsigned long gp3_dst_stride; CIMARRON_STATIC unsigned long gp3_src_format; CIMARRON_STATIC unsigned long gp3_src_pix_shift; CIMARRON_STATIC unsigned long gp3_pat_format; CIMARRON_STATIC unsigned long gp3_pat_pix_shift; CIMARRON_STATIC unsigned long gp3_fb_base; CIMARRON_STATIC unsigned long gp3_vector_pattern_color; CIMARRON_STATIC unsigned long gp3_scratch_base; CIMARRON_STATIC unsigned long gp3_base_register; CIMARRON_STATIC unsigned long gp3_vec_pat; /*--------------------------------------------------------------------------- * gp_set_limit_on_buffer_lead * * This routine is used to specify the maximum number of bytes in the command * buffer by which software can lead the graphics processor. When declaring * a BLT with the CIMGP_BLTFLAGS_LIMITBUFFER flag set, Cimarron will wait * until the command buffer read and write pointers differ by no more than * 'lead' bytes. This can be useful to limit the time lag possible when * creating a command buffer full of simple BLT commands. *-------------------------------------------------------------------------*/ void gp_set_limit_on_buffer_lead(unsigned long lead) { gp3_buffer_lead = lead; } /*--------------------------------------------------------------------------- * gp_set_command_buffer_base * * This routine is used to program the command buffer region in physical * memory. The command buffer start address must be 1MB aligned. start and * stop refer to endpoints within the associated 16MB region. Command buffers * larger than 16MB are not supported. *-------------------------------------------------------------------------*/ void gp_set_command_buffer_base(unsigned long address, unsigned long start, unsigned long stop) { Q_WORD msr_value; /* WAIT FOR IDLE */ /* Obviously, we cannot change the command buffer pointer while the GP */ /* is currently fetching commands. */ gp_wait_until_idle(); /* WRITE THE COMMAND BUFFER BASE */ msr_read64(MSR_DEVICE_GEODELX_GP, MSR_GEODELINK_CONFIG, &msr_value); msr_value.low &= 0xF000FFFF; msr_value.low |= (address >> 4) & 0x0FFF0000; msr_write64(MSR_DEVICE_GEODELX_GP, MSR_GEODELINK_CONFIG, &msr_value); /* WRITE THE BASE OFFSETS */ /* We also reset the write and read pointers. The hardware will */ /* automatically update the write pointer when the read pointer */ /* is updated to prevent the hardware from getting confused when */ /* initializing a new command buffer. */ WRITE_GP32(GP3_CMD_TOP, start); WRITE_GP32(GP3_CMD_BOT, stop); WRITE_GP32(GP3_CMD_READ, start); /* SAVE THE BASE ADDRESSES */ /* These are used to determine the appropriate wrap point. */ gp3_cmd_current = gp3_cmd_top = start; gp3_cmd_bottom = stop; } /*--------------------------------------------------------------------------- * gp_set_frame_buffer_base * * This routine is used to program the base address of the frame buffer in * physical memory. The frame buffer address must be 16MB aligned. Cimarron * tracks the base address because the maximum frame buffer size may exceed * 16MB. Any primitive will thus program the corresponding 16MB region into * all base offset registers as well as program the offset into the 16MB * region. The size parameter is provided to allow Cimarron to claim the * last 1MB of space to be used as a scratch area for workarounds or * expanded functionality. *-------------------------------------------------------------------------*/ void gp_set_frame_buffer_base(unsigned long address, unsigned long size) { gp3_scratch_base = size - GP3_SCRATCH_BUFFER_SIZE; gp3_fb_base = address >> 24; gp3_base_register = (gp3_fb_base << 24) | (gp3_fb_base << 14) | (gp3_fb_base << 4); WRITE_GP32(GP3_BASE_OFFSET, gp3_base_register); } /*--------------------------------------------------------------------------- * gp_set_bpp * * This routine sets the output BPP of the GP. The BPP used by the GP does * not have to match the display BPP, but that is usually the case. The * supported BPP values are as follows: * * 8 - palettized 8BPP * 12 - 4:4:4:4 * 15 - 1:5:5:5 * 16 - 0:5:6:5 * 32 - 8:8:8:8 *-------------------------------------------------------------------------*/ void gp_set_bpp(int bpp) { /* STORE BPP */ /* The bpp is not updated until the next call to gp_set_raster_mode. */ /* This allows the gp_set_bpp call to happen outside of a BLT. It */ /* also implies that no registers need be written in this routine. */ switch (bpp) { case 8: gp3_bpp = GP3_RM_BPPFMT_332; gp3_ch3_bpp = GP3_CH3_SRC_3_3_2; gp3_pix_shift = 0; break; case 12: gp3_bpp = GP3_RM_BPPFMT_4444; gp3_ch3_bpp = GP3_CH3_SRC_4_4_4_4; gp3_pix_shift = 1; break; case 15: gp3_bpp = GP3_RM_BPPFMT_1555; gp3_ch3_bpp = GP3_CH3_SRC_1_5_5_5; gp3_pix_shift = 1; break; case 16: gp3_bpp = GP3_RM_BPPFMT_565; gp3_ch3_bpp = GP3_CH3_SRC_0_5_6_5; gp3_pix_shift = 1; break; case 24: case 32: gp3_bpp = GP3_RM_BPPFMT_8888; gp3_ch3_bpp = GP3_CH3_SRC_8_8_8_8; gp3_pix_shift = 2; break; default: gp3_bpp = GP3_RM_BPPFMT_332; gp3_ch3_bpp = GP3_CH3_SRC_3_3_2; gp3_pix_shift = 0; break; } } /*--------------------------------------------------------------------------- * gp_declare_blt * * This routine is used to prepare for a 2D BLT. Its primary function * is to verify that enough room is available in the command buffer * to hold a BLT command. This command can be called multiple times if * necessary. For example, if a function calls this routine on entry, but * later realizes that a LUT load command must be executed before the BLT, * the application could call gp_set_color_pattern and then call * gp_declare_blt to declare the BLT. This is possible because the hardware * buffer pointer is not updated until a new BLT is actually executed. An * application must take care not to call any routines that perform a buffer * command, (such as gp_set_color_pattern) between gp_declare_blt and the * routines used to program the BLT parameters. In addition to checking for * available space, this routine also performs the following actions: * - Sets the wrap bit if this BLT will pass close to the end of the * buffer. * - Writes the command header. * * The available flags are defined as follows: * 0x01 - Preserve the LUT * 0x02 - Preserve the color pattern. * 0x04 - Enable prefetch. *-------------------------------------------------------------------------*/ void gp_declare_blt(unsigned long flags) { unsigned long temp; gp3_blt = 1; gp3_blt_flags = flags; /* SET ADDRESS OF NEXT COMMAND */ /* A summary of the command buffer logic is as follows: */ /* - If after a basic BLT we will not have room for the largest */ /* command (a full line of host source data), we set the wrap */ /* bit. This will waste up to a whopping 8K of command buffer */ /* space, but it simplifies the logic for all commands. */ /* - If we are wrapping, we have extra logic to ensure that we */ /* don't skip over the current GP read pointer. */ gp3_cmd_next = gp3_cmd_current + GP3_BLT_COMMAND_SIZE; /* CHECK WRAP CONDITION */ if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; gp3_cmd_header = GP3_BLT_HDR_TYPE | GP3_BLT_HDR_WRAP; /* WAIT FOR HARDWARE */ /* When wrapping, we must take steps to ensure that we do not */ /* wrap over the current hardware read pointer. We do this by */ /* verifying that the hardware is not between us and the end of */ /* the command buffer. We also have a special case to make sure */ /* that the hardware is not currently reading the top of the */ /* command buffer. */ GP3_WAIT_WRAP(temp); } else { gp3_cmd_header = GP3_BLT_HDR_TYPE; /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); } if (flags & CIMGP_BLTFLAGS_LIMITBUFFER) { while (1) { temp = READ_GP32(GP3_CMD_READ); if (((gp3_cmd_current >= temp) && ((gp3_cmd_current - temp) <= gp3_buffer_lead)) || ((gp3_cmd_current < temp) && ((gp3_cmd_current + (gp3_cmd_bottom - temp)) <= gp3_buffer_lead))) { break; } } } /* SET THE CURRENT BUFFER POINTER */ /* We initialize a pointer to the current buffer base to avoid an */ /* extra addition for every buffer write. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* SET THE HAZARD BIT */ if (flags & CIMGP_BLTFLAGS_HAZARD) gp3_cmd_header |= GP3_BLT_HDR_HAZARD_ENABLE; } /*--------------------------------------------------------------------------- * gp_declare_vector * * This routine is used to prepare for a 2D vector. It has no other function * except to verify that enough room is available in the command buffer * to hold a vector command. The same rules that apply to BLTs apply to * vectors. (See the documentation for gp_declare_blt). *-------------------------------------------------------------------------*/ void gp_declare_vector(unsigned long flags) { unsigned long temp; gp3_blt = 0; gp3_blt_flags = flags; /* SET ADDRESS OF NEXT COMMAND */ /* The logic to force a wrap during a vector is identical */ /* to the BLT logic. */ /* ALLOCATE SPACE FOR AN ADDITIONAL VECTOR TO CLEAR THE BYTE ENABLES */ gp3_cmd_next = gp3_cmd_current + GP3_VECTOR_COMMAND_SIZE + GP3_VECTOR_COMMAND_SIZE + 32; /* CHECK WRAP CONDITION */ if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; gp3_cmd_header = GP3_VEC_HDR_TYPE | GP3_VEC_HDR_WRAP; /* CHECK WRAP CONDITION */ GP3_WAIT_WRAP(temp); } else { gp3_cmd_header = GP3_VEC_HDR_TYPE; /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); gp3_cmd_next -= GP3_VECTOR_COMMAND_SIZE + 32; } if (flags & CIMGP_BLTFLAGS_LIMITBUFFER) { while (1) { temp = READ_GP32(GP3_CMD_READ); if (((gp3_cmd_current >= temp) && ((gp3_cmd_current - temp) <= gp3_buffer_lead)) || ((gp3_cmd_current < temp) && ((gp3_cmd_current + (gp3_cmd_bottom - temp)) <= gp3_buffer_lead))) { break; } } } cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* SET THE HAZARD BIT */ if (flags & CIMGP_BLTFLAGS_HAZARD) gp3_cmd_header |= GP3_VEC_HDR_HAZARD_ENABLE; } /*--------------------------------------------------------------------------- * gp_write_parameters * * This routine is called to write all recent parameters to the hardware. * This routine is necessary for any implementation that performs the setup * for a BLT separate from the actual BLT. An example would be a driver * that prepares for multiple pattern fills by programming the ROP, * pattern color and destination stride. The driver might then perform * repeated pattern fills with minimal effort. *-------------------------------------------------------------------------*/ void gp_write_parameters(void) { /* WRITE THE COMMAND HEADER */ /* Command header is at offset 0 for BLTs and vectors */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); /* INCREMENT THE CURRENT WRITE POINTER */ gp3_cmd_current = gp3_cmd_next; /* UPDATE THE GP WRITE POINTER */ WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_current); } /*--------------------------------------------------------------------------- * gp_set_raster_operation * * This is generally the first routine called when programming a BLT. This * routine performs the following functions: * - Sets the initial value of the GP3_RASTER_MODE register in the buffer. * - Clears any 8x8 pattern if the ROP does not involve pattern data. *-------------------------------------------------------------------------*/ void gp_set_raster_operation(unsigned char ROP) { gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE; /* WRITE THE RASTER MODE REGISTER */ /* This register is in the same location in BLT and vector commands */ gp3_raster_mode = gp3_bpp | (unsigned long) ROP; WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode); /* CHECK IF DESTINATION IS REQUIRED */ if ((ROP & 0x55) ^ ((ROP >> 1) & 0x55)) { gp3_blt_mode = GP3_BM_DST_REQ; gp3_vec_mode = GP3_VM_DST_REQ; } else { gp3_blt_mode = gp3_vec_mode = 0; } } /*---------------------------------------------------------------------------- * gp_set_alpha_operation * * BLTs are generally one of two types, a ROPed BLT or a BLT composited using * alpha blending. For the latter, this routine is used to configure the * mathematical function used to create the blended output. This routine * should generally be called first when programming a BLT. The available * parameters mirror the hardware and are described as follows: * * alpha_operation = * 0 - alpha * A * 1 - (1 - alpha) * B * 2 - A + (1 - alpha)*B * 3 - alpha*A + (1 - alpha)*B * * alpha_type = * 0 - alpha component of channel A * 1 - alpha component of channel B * 2 - Constant alpha * 3 - Constant 1 * 4 - The color components of channel A * 5 - The color components of channel B * 6 - Alpha comes from the alpha channel of the source before the source * undergoes color conversion. * * channel = * 0 - Channel A = source, channel B = destination * 1 - Channel B = source, channel A = destination * * apply_alpha = * 1 - Apply alpha blend to only the RGB portion of the pixel. This must be * set when the source or destination format do not include an alpha * channel. * 2 - Apply alpha blend only to the alpha portion of the pixel. This * implies that both destination and source include an alpha channel. * 3 - Apply alpha blend to both the RGB and alpha portions of the pixel. * * Alpha-blended vectors are not currently supported. *-------------------------------------------------------------------------*/ void gp_set_alpha_operation(int alpha_operation, int alpha_type, int channel, int apply_alpha, unsigned char alpha) { gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE; /* THE AVAILABLE ALPHA DEFINITIONS FOLLOW THE HARDWARE */ /* This allows us to avoid giant switch structures, but it */ /* also implies that there is no mechanism to detect invalid */ /* parameters. */ gp3_raster_mode = gp3_bpp | (unsigned long) alpha | ((unsigned long) apply_alpha << 22) | ((unsigned long) alpha_operation << 20) | ((unsigned long) alpha_type << 17) | ((unsigned long) channel << 16); WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode); /* CHECK IF DESTINATION IS REQUIRED */ if ((alpha_operation == CIMGP_ALPHA_TIMES_A && channel == CIMGP_CHANNEL_A_SOURCE && alpha_type != CIMGP_CHANNEL_B_ALPHA && alpha_type != CIMGP_ALPHA_FROM_RGB_B) || (alpha_operation == CIMGP_BETA_TIMES_B && channel == CIMGP_CHANNEL_A_DEST && alpha_type != CIMGP_CHANNEL_A_ALPHA && alpha_type != CIMGP_ALPHA_FROM_RGB_A)) { gp3_blt_mode = 0; } else gp3_blt_mode = GP3_BM_DST_REQ; } /*--------------------------------------------------------------------------- * gp_set_solid_pattern * * This routine is called to program the hardware for a solid pattern. It * need not be called for any other reason. As a side effect, this routine * will clear any 8x8 pattern data. *-------------------------------------------------------------------------*/ void gp_set_solid_pattern(unsigned long color) { /* CHANNEL 3 IS NOT NEEDED FOR SOLID PATTERNS */ gp3_ch3_pat = 0; /* SET SOLID PATTERN IN COMMAND BUFFER */ /* We are assuming that only one pattern type is ever set for a */ /* BLT. We are also assuming that gp_set_raster_operation will */ /* be called before this routine. With these assumptions, we */ /* will thus never have to change the raster mode register for */ /* solid patterns. */ if (gp3_blt) { gp3_cmd_header |= GP3_BLT_HDR_PAT_CLR0_ENABLE; WRITE_COMMAND32(GP3_BLT_PAT_COLOR_0, color); } else { gp3_cmd_header |= GP3_VEC_HDR_PAT_CLR0_ENABLE; WRITE_COMMAND32(GP3_VECTOR_PAT_COLOR_0, color); } } /*--------------------------------------------------------------------------- * gp_set_mono_pattern * * This routine is called to program the hardware for a monochrome pattern. * As a side effect, this routine will clear any 8x8 pattern data. *-------------------------------------------------------------------------*/ void gp_set_mono_pattern(unsigned long bgcolor, unsigned long fgcolor, unsigned long data0, unsigned long data1, int transparent, int x, int y) { /* CHANNEL 3 IS NOT NEEDED FOR MONOCHROME PATTERNS */ gp3_ch3_pat = 0; /* UPDATE RASTER MODE REGISTER */ if (transparent) gp3_raster_mode |= GP3_RM_PAT_MONO | GP3_RM_PAT_TRANS; else gp3_raster_mode |= GP3_RM_PAT_MONO; gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE; WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode); /* SET MONOCHROME PATTERN DATA AND COLORS */ if (gp3_blt) { gp3_cmd_header |= (GP3_BLT_HDR_PAT_CLR0_ENABLE | GP3_BLT_HDR_PAT_CLR1_ENABLE | GP3_BLT_HDR_PAT_DATA0_ENABLE | GP3_BLT_HDR_PAT_DATA1_ENABLE); WRITE_COMMAND32(GP3_BLT_PAT_COLOR_0, bgcolor); WRITE_COMMAND32(GP3_BLT_PAT_COLOR_1, fgcolor); WRITE_COMMAND32(GP3_BLT_PAT_DATA_0, data0); WRITE_COMMAND32(GP3_BLT_PAT_DATA_1, data1); } else { gp3_cmd_header |= (GP3_VEC_HDR_PAT_CLR0_ENABLE | GP3_VEC_HDR_PAT_CLR1_ENABLE | GP3_VEC_HDR_PAT_DATA0_ENABLE | GP3_VEC_HDR_PAT_DATA1_ENABLE); WRITE_COMMAND32(GP3_VECTOR_PAT_COLOR_0, bgcolor); WRITE_COMMAND32(GP3_VECTOR_PAT_COLOR_1, fgcolor); WRITE_COMMAND32(GP3_VECTOR_PAT_DATA_0, data0); WRITE_COMMAND32(GP3_VECTOR_PAT_DATA_1, data1); } /* SAVE PATTERN ORIGIN */ gp3_pat_origin = ((unsigned long) y << 29) | (((unsigned long) x & 7) << 26); } /*--------------------------------------------------------------------------- * gp_set_pattern_origin * * This routine overrides the pattern origins set in gp_set_mono_pattern or * gp_set_color_pattern. It is generally used to override the original * pattern origin due to a change in clipping. *-------------------------------------------------------------------------*/ void gp_set_pattern_origin(int x, int y) { /* SAVE PATTERN ORIGIN */ gp3_pat_origin = ((unsigned long) y << 29) | (((unsigned long) x & 7) << 26); } /*--------------------------------------------------------------------------- * gp_set_color_pattern * * This routine is called to program a 8x8 color pattern into the LUT * hardware. Unlike the other pattern routines, this routine must be called * before any gp_declare_xxxx routines. The pattern that is programmed into * the hardware will stay persistent for all subsequent primitives until one * of the following conditions happens. * - Another pattern type is programmed. * - A color-conversion BLT rotation BLT. *-------------------------------------------------------------------------*/ void gp_set_color_pattern(unsigned long *pattern, int format, int x, int y) { unsigned long size_dwords, temp; gp3_ch3_pat = 1; /* SAVE COLOR PATTERN SOURCE INFO * Color patterns can be in a format different than the primary display. * 4BPP patterns are not supported. */ gp3_pat_pix_shift = (unsigned long) ((format >> 2) & 3); gp3_pat_format = (((unsigned long) format & 0xF) << 24) | (((unsigned long) format & 0x10) << 17) | GP3_CH3_COLOR_PAT_ENABLE | GP3_CH3_C3EN; size_dwords = (64 << gp3_pat_pix_shift) >> 2; /* CHECK FOR WRAP AFTER LUT LOAD */ /* Primitive size is 12 plus the amount of data. */ gp3_cmd_next = gp3_cmd_current + (size_dwords << 2) + 12; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; gp3_cmd_header = GP3_LUT_HDR_TYPE | GP3_LUT_HDR_WRAP | GP3_LUT_HDR_DATA_ENABLE; /* WAIT FOR HARDWARE */ /* Same logic as BLT wrapping. */ GP3_WAIT_WRAP(temp); } else { gp3_cmd_header = GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE; /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); } /* SAVE CURRENT BUFFER POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* PREPARE FOR COMMAND BUFFER DATA WRITES */ /* Pattern data is contiguous DWORDs at LUT address 0x100 */ WRITE_COMMAND32(0, gp3_cmd_header); WRITE_COMMAND32(4, 0x100); WRITE_COMMAND32(8, size_dwords | GP3_LUT_DATA_TYPE); /* WRITE ALL DATA */ WRITE_COMMAND_STRING32(12, pattern, 0, size_dwords); /* START OPERATION */ WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* SAVE PATTERN ORIGIN */ gp3_pat_origin = ((unsigned long) y << 29) | (((unsigned long) x & 7) << 26); } /*--------------------------------------------------------------------------- * gp_set_mono_source * * This routine is called to program the colors for monochrome source data. *-------------------------------------------------------------------------*/ void gp_set_mono_source(unsigned long bgcolor, unsigned long fgcolor, int transparent) { /* UPDATE RASTER MODE REGISTER IF TRANSPARENT */ if (transparent) { gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE; gp3_raster_mode |= GP3_RM_SRC_TRANS; WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode); } /* SET MONOCHROME SOURCE COLORS */ /* Note that this routine only sets the colors. The actual */ /* source type is determined by the final output routine */ /* (gp_mono_bitmap_xxx, gp_color_bitmap_xxx, etc.) */ gp3_cmd_header |= GP3_BLT_HDR_SRC_FG_ENABLE | GP3_BLT_HDR_SRC_BG_ENABLE; WRITE_COMMAND32(GP3_BLT_SRC_COLOR_FG, fgcolor); WRITE_COMMAND32(GP3_BLT_SRC_COLOR_BG, bgcolor); } /*--------------------------------------------------------------------------- * gp_set_solid_source * * This routine is called to program a solid source color. A solid source * color is used primarily for vectors or antialiased text. *-------------------------------------------------------------------------*/ void gp_set_solid_source(unsigned long color) { /* SET SOLID SOURCE COLOR */ /* The solid source register is in the same place for both BLTs and */ /* vectors. */ gp3_cmd_header |= GP3_BLT_HDR_SRC_FG_ENABLE; WRITE_COMMAND32(GP3_BLT_SRC_COLOR_FG, color); } /*--------------------------------------------------------------------------- * gp_set_source_transparency * * This routine sets the source transparency and mask to be used in future * rendering operations. Transparency is cleared by gp_set_raster_operation, * so this routine should never be called first. *-------------------------------------------------------------------------*/ void gp_set_source_transparency(unsigned long color, unsigned long mask) { gp3_raster_mode |= GP3_RM_SRC_TRANS; gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_SRC_FG_ENABLE | GP3_BLT_HDR_SRC_BG_ENABLE; WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode); WRITE_COMMAND32(GP3_BLT_SRC_COLOR_FG, color); WRITE_COMMAND32(GP3_BLT_SRC_COLOR_BG, mask); } /*--------------------------------------------------------------------------- * gp_program_lut * * This routine is called to program the hardware LUT with color-conversion * information. This routine should be called before any gp_declare_xxxx * routines. * * colors - Pointer to an array of DWORDs for color expansion. * * full_lut - Selector between 4BPP and 8BPP expansion. The hardware is * initialized with 16 dwords for 4BPP expansion and 256 dwords * for 8BPP expansion. *-------------------------------------------------------------------------*/ void gp_program_lut(unsigned long *colors, int full_lut) { unsigned long size_dwords, temp; /* SIZE IS EITHER 16 DWORDS (4BPP) or 256 DWORDS (8BPP) */ if (full_lut) size_dwords = 256; else size_dwords = 16; /* CHECK FOR WRAP AFTER LUT LOAD */ /* Primitive size is 12 plus the amount of data. */ gp3_cmd_next = gp3_cmd_current + (size_dwords << 2) + 12; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; gp3_cmd_header = GP3_LUT_HDR_TYPE | GP3_LUT_HDR_WRAP | GP3_LUT_HDR_DATA_ENABLE; /* WAIT FOR HARDWARE */ /* Same logic as BLT wrapping. */ GP3_WAIT_WRAP(temp); } else { gp3_cmd_header = GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE; /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); } /* SAVE CURRENT BUFFER POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* PREPARE FOR COMMAND BUFFER DATA WRITES */ /* Pattern data is contiguous DWORDs at LUT address 0 */ WRITE_COMMAND32(0, gp3_cmd_header); WRITE_COMMAND32(4, 0); WRITE_COMMAND32(8, (size_dwords | GP3_LUT_DATA_TYPE)); /* WRITE ALL DATA */ WRITE_COMMAND_STRING32(12, colors, 0, size_dwords); /* START OPERATION */ WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_set_vector_pattern * * This routine is called to program the hardware LUT with a vector pattern. * A vector pattern is programmed as a 32-bit mask that specifies a * transparency pattern. A length parameter is used to specify patterns * smaller than 32. Note that vectors in Geode LX do not continue across * corners. The beginning of each vector will always begin with bit 0 of the * vector pattern. It is the responsibility of the caller to update the * pattern if an alternate behavior is desired. * * This routine faces the same restrictions of all routines that program * the LUT, in that it must be called before any gp_declare_xxxx routines, * it cannot be combined with an 8x8 color pattern, color conversion or * rotation. *-------------------------------------------------------------------------*/ void gp_set_vector_pattern(unsigned long pattern, unsigned long color, int length) { unsigned long temp, mask; gp3_ch3_pat = 1; gp3_vector_pattern_color = color; /* CREATE SUITABLE PATTERN MASK */ /* The GP requires a minimum of four pixels in a vector pattern. We */ /* can get around this restriction by doubling any patterns smaller */ /* than 4 pixels. */ while (length < 4) { mask = 0xFFFFFFFF >> (32 - length); pattern = (pattern << length) | (pattern & mask); length <<= 1; } mask = 0xFFFFFFFF >> (32 - length); gp3_vec_pat = pattern; /* CHECK FOR WRAP AFTER LUT LOAD */ gp3_cmd_next = gp3_cmd_current + GP3_VECTOR_PATTERN_COMMAND_SIZE; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; gp3_cmd_header = GP3_LUT_HDR_TYPE | GP3_LUT_HDR_WRAP | GP3_LUT_HDR_DATA_ENABLE; /* WAIT FOR HARDWARE */ /* Same logic as BLT wrapping. */ GP3_WAIT_WRAP(temp); } else { gp3_cmd_header = GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE; /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); } /* SAVE CURRENT BUFFER POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* PREPARE FOR COMMAND BUFFER DATA WRITES */ /* Pattern data is 2 DWORDs at 0x100 and 0x101 */ WRITE_COMMAND32(0, gp3_cmd_header); WRITE_COMMAND32(4, 0x100); WRITE_COMMAND32(8, (2 | GP3_LUT_DATA_TYPE)); WRITE_COMMAND32(12, pattern); WRITE_COMMAND32(16, mask); /* START OPERATION */ WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_set_strides * * This routine is called to program the pitch between successive lines of * data in the frame buffer. The strides should be DWORD aligned and less * than 64K. These restrictions are not checked by the API. *-------------------------------------------------------------------------*/ void gp_set_strides(unsigned long dst_stride, unsigned long src_stride) { /* SAVE STRIDES */ /* The source stride may be needed later for channel 3 source data and */ /* we may need to use these strides in calculations. */ gp3_src_stride = src_stride; gp3_dst_stride = dst_stride; /* ENABLE STRIDES */ /* The stride register is in the same place for BLTs and vectors */ gp3_cmd_header |= GP3_BLT_HDR_STRIDE_ENABLE; WRITE_COMMAND32(GP3_BLT_STRIDE, ((src_stride << 16) | dst_stride)); } /*--------------------------------------------------------------------------- * gp_set_source_format * * This routine is used to program the format of source data used in * subsequent color-conversion or rotation operations. Note that 4BPP * indexed and 8BPP indexed source formats cannot be used when rotating, as * the LUT will be destroyed. These formats also cannot be combined with an * 8x8 color pattern. The supported formats mirror the hardware and are * described as follows: * * 0 - 8BPP 3:3:2 * 1 - 8BPP indexed * 4 - 16BPP 4:4:4:4 * 5 - 16BPP 1:5:5:5 * 6 - 16BPP 5:6:5 * 7 - 16BPP YUV * 8 - 32BPP 8:8:8:8 * 13 - 4BPP indexed * 20 - 16BPP 4:4:4:4 BGR * 21 - 16BPP 1:5:5:5 BGR * 22 - 16BPP 0:5:6:5 BGR * 24 - 32BPP 8:8:8:8 BGR *-------------------------------------------------------------------------*/ void gp_set_source_format(int format) { /* SAVE FORMAT */ /* We will combine the source format later when doing color conversion. */ /* We also save the pixel size for host source calculations. */ /* Conveniently, the source formats are organized such that the upper */ /* two bits of the nibble represent the pixel shift, with a pixel shift */ /* of 3 being a special case for 4BPP data. Clever, yes? Even more */ /* clever, bit 4 indicates BGR ordering. */ gp3_src_pix_shift = (unsigned long) ((format >> 2) & 3); gp3_src_format = (((unsigned long) format & 0xF) << 24) | (((unsigned long) format & 0x10) << 18); } /*--------------------------------------------------------------------------- * gp_pattern_fill * * This routine is called to perform a simple pattern fill. The pattern * can be solid, monochrome or a preprogrammed 8x8 color pattern. If * the ROP involves source data, that source data will be constant. *-------------------------------------------------------------------------*/ void gp_pattern_fill(unsigned long dstoffset, unsigned long width, unsigned long height) { unsigned long base_register; base_register = (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK) | ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)); /* ENABLE RELEVANT REGISTERS */ /* Note that we always enable and write the channel 3 mode, if only */ /* to turn it off. Cimarron also always writes the base offset */ /* register to allow operation with frame buffers larger than 16MB. */ gp3_cmd_header |= GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* WRITE THE REGISTERS COMMON TO ALL PATTERN TYPES */ /* The destination base is the frame buffer base plus whatever */ /* 4MB segment we happen to be BLTing to. */ WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, ((width << 16) | height)); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base_register); /* CHECK 8X8 COLOR PATTERN CASE */ if (gp3_ch3_pat) { /* SET CHANNEL 3 PATTERN ORIGINS */ gp3_cmd_header |= GP3_BLT_HDR_CH3_OFF_ENABLE; /* INITIALIZE CHANNEL 3 PARAMETERS */ WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, ((width << 16) | height)); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoffset & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, gp3_pat_format); } else { /* DISABLE CHANNEL 3 AND USE NORMAL PATTERN ORIGINS */ WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, 0); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, ((dstoffset & 0x3FFFFF) | gp3_pat_origin)); } /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_screen_to_screen_blt * * This routine is called to perform a BLT from one location inside video * memory to another location inside video memory. The source and destination * formats are assumed to be the current BPP. Whenever possible, this routine * tries to use channel 3 to fetch source data. The BLT flags can affect this * behavior in the following ways: * CIMGP_BLTFLAGS_PRES_COLOR_PAT * A color pattern is being stored in the channel 3 buffer. It is either * being stored for a later BLT or being combined with the current source * data. Channel 3 cannot be used to fetch source data or the pattern * will be overwritten. * CIMGP_BLTFLAGS_PRES_LUT * If the first flag is not set, this flag will limit the use of the * channel 3 buffer to 1K. *-------------------------------------------------------------------------*/ void gp_screen_to_screen_blt(unsigned long dstoffset, unsigned long srcoffset, unsigned long width, unsigned long height, int flags) { unsigned long base; unsigned long ch3_flags = 0; unsigned long blt_mode = gp3_blt_mode; unsigned long size = ((width << 16) | height); unsigned long dstbase, srcbase; /* CALCULATE BASE OFFSETS */ /* We need to set the 4MB aligned base offsets before we add offsets */ /* for negative BLTs. */ srcbase = srcoffset & 0xFFC00000; dstbase = dstoffset & 0xFFC00000; srcoffset &= 0x3FFFFF; dstoffset &= 0x3FFFFF; /* ADJUST OFFSETS BASED ON FLAGS */ /* We adjust the source and destination offsets to point to the first */ /* byte of the first pixel of the BLT. This routine assumes that the */ /* source and destination regions do not wrap past the end of a 16MB */ /* region. */ if (flags & CIMGP_NEGXDIR) { srcoffset += (width << gp3_pix_shift) - 1; dstoffset += (width << gp3_pix_shift) - 1; blt_mode |= GP3_BM_NEG_XDIR; ch3_flags |= GP3_CH3_NEG_XDIR; } if (flags & CIMGP_NEGYDIR) { srcoffset += (height - 1) * gp3_src_stride; dstoffset += (height - 1) * gp3_dst_stride; blt_mode |= GP3_BM_NEG_YDIR; ch3_flags |= GP3_CH3_NEG_YDIR; } /* BRANCH BASED ON CHANNEL 3 */ /* If a color pattern is not being saved or used, channel 3 will */ /* be used to fetch source for maximum throughput. Channel 3 */ /* is not used if transparency or alpha blending is enabled. */ if (!(gp3_blt_flags & CIMGP_BLTFLAGS_PRES_COLOR_PAT) && !(gp3_raster_mode & GP3_RM_SRC_TRANS) && !(flags & CIMGP_NEGYDIR)) { base = ((gp3_fb_base << 24) + dstbase) | ((gp3_fb_base << 4) + (srcbase >> 20)) | (gp3_base_register & GP3_BASE_OFFSET_SRCMASK); gp3_cmd_header |= GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset | gp3_pat_origin)); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, srcoffset); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | gp3_ch3_bpp | gp3_src_stride | ch3_flags | ((gp3_blt_flags & CIMGP_ENABLE_PREFETCH) << 17) | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); } else { /* CALCULATE BASE OFFSET REGISTER */ base = ((gp3_fb_base << 24) + dstbase) | ((gp3_fb_base << 14) + (srcbase >> 10)) | (gp3_base_register & GP3_BASE_OFFSET_CH3MASK); /* PROGRAM THE NORMAL SOURCE CHANNEL REGISTERS */ /* We assume that a color pattern is being ROPed with source */ /* data if the pattern type is color and the preserve pattern */ /* was set. */ blt_mode |= GP3_BM_SRC_FB; gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; if (gp3_ch3_pat) { WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoffset); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, gp3_pat_format | ch3_flags); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); } else { WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoffset | gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, 0); } WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, srcoffset); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); } /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_screen_to_screen_convert * * This routine is called to color-convert a rectangular region of the frame * buffer into the current BPP. The format of the source region is programmed * by gp_set_source_format. *-------------------------------------------------------------------------*/ void gp_screen_to_screen_convert(unsigned long dstoffset, unsigned long srcoffset, unsigned long width, unsigned long height, int nibble) { unsigned long size = ((width << 16) | height); unsigned long ch3_offset = srcoffset & 0x3FFFFF; unsigned long ch3_size, base; base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | ((gp3_fb_base << 4) + ((srcoffset & 0xFFC00000) >> 20)) | (gp3_base_register & GP3_BASE_OFFSET_SRCMASK); /* SET NIBBLE FOR 4BPP */ /* 4BPP is a special case in that it requires subpixel addressing. The */ /* user must supply this information via the nibble parameter. This */ /* parameter is ignored for every other source format. */ ch3_size = size; if (gp3_src_pix_shift == 3) ch3_offset |= ((nibble & 1) << 25); else if ((gp3_src_format & GP3_CH3_SRC_MASK) == GP3_CH3_SRC_24BPP_PACKED) ch3_size = ((((width * 3) + 3) >> 2) << 16) | height; /* SET APPROPRIATE ENABLES */ gp3_cmd_header |= GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* WRITE ALL BLT REGISTERS */ WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF) | gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, ch3_size); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, ch3_offset); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | gp3_src_format | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20) | ((gp3_blt_flags & CIMGP_ENABLE_PREFETCH) << 17) | gp3_src_stride); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_color_bitmap_to_screen_blt * * This routine is called to BLT data from system memory into the frame * buffer. 'srcy' is deliberately omitted to prevent extra calculations for * simple applications that have no source indexes. *-------------------------------------------------------------------------*/ void gp_color_bitmap_to_screen_blt(unsigned long dstoffset, unsigned long srcx, unsigned long width, unsigned long height, unsigned char *data, long pitch) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long size = ((width << 16) | height); unsigned long srcoffset; /* ASSUME BITMAPS ARE DWORD ALIGNED */ /* We will offset into the source data in DWORD increments. We */ /* set the source index to the remaining byte offset and */ /* increment the size of each line to account for the dont-care */ /* pixel(s). */ indent = srcx << gp3_pix_shift; srcoffset = (indent & ~3L); indent &= 3; /* PROGRAM THE NORMAL SOURCE CHANNEL REGISTERS */ /* We assume that a color pattern is being ROPed with source */ /* data if the pattern type is color and the preserve pattern */ /* was set. */ gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; if (gp3_ch3_pat) { gp3_cmd_header |= GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, gp3_pat_format); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); } else { WRITE_COMMAND32(GP3_BLT_DST_OFFSET, ((dstoffset & 0x3FFFFF) | gp3_pat_origin)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, 0); } WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, indent); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000))); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode | GP3_BM_SRC_HOST); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* CALCULATE THE SIZE OF ONE LINE */ size = (width << gp3_pix_shift) + indent; total_dwords = (size + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (size >> 2); byte_count = (size & 3); /* CHECK FOR SMALL BLT CASE */ if (((total_dwords << 2) * height) <= GP3_BLT_1PASS_SIZE && (gp3_cmd_bottom - gp3_cmd_current) > (GP3_BLT_1PASS_SIZE + 72)) { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + ((total_dwords << 2) * height) + 8; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_HOST_SOURCE_TYPE | (total_dwords * height)); while (height--) { /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); srcoffset += pitch; cim_cmd_ptr += total_dwords << 2; } WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } else { /* * Each line will be created as a separate command buffer entry to * allow line-by-line wrapping and to allow simultaneous rendering * by the HW. */ while (height--) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoffset += pitch; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } } } /*--------------------------------------------------------------------------- * gp_color_convert_blt * * This routine is called to convert data that is stored in system memory * into the current graphics BPP. The source format is programmed in * gp_set_source_format. *-------------------------------------------------------------------------*/ void gp_color_convert_blt(unsigned long dstoffset, unsigned long srcx, unsigned long width, unsigned long height, unsigned char *data, long pitch) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long size = ((width << 16) | height); unsigned long ch3_size; unsigned long ch3_offset, srcoffset; unsigned long base; /* ASSUME BITMAPS ARE DWORD ALIGNED */ /* We will offset into the source data in DWORD increments. We */ /* set the source index to the remaining byte offset and */ /* increment the size of each line to account for the dont-care */ /* pixel(s). For 4BPP source data, we also set the appropriate */ /* nibble index. */ /* CALCULATE THE SIZE OF ONE LINE */ if ((gp3_src_format & GP3_CH3_SRC_MASK) == GP3_CH3_SRC_24BPP_PACKED) { /* HANDLE 24BPP * Note that we do not do anything to guarantee that the source data * is DWORD aligned. The logic here is that the source data will be * cacheable, in which case Geode LX will not lose any clocks for * unaligned moves. Also note that the channel 3 width is * programmed as the number of dwords, while the normal width is * programmed as the number of pixels. */ srcoffset = srcx * 3; ch3_offset = 0; temp = width * 3; ch3_size = (((temp + 3) >> 2) << 16) | height; } else { ch3_size = size; if (gp3_src_pix_shift == 3) { /* CALCULATE INDENT AND SOURCE OFFSET */ indent = (srcx >> 1); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent | ((srcx & 1) << 25); temp = ((width + (srcx & 1) + 1) >> 1) + indent; } else { indent = (srcx << gp3_src_pix_shift); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent; temp = (width << gp3_src_pix_shift) + indent; } } total_dwords = (temp + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (temp >> 2); byte_count = (temp & 3); base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); /* SET APPROPRIATE ENABLES */ gp3_cmd_header |= GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF) | gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, ch3_offset); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, ch3_size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_HST_SRC_ENABLE | gp3_src_format | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; if (((total_dwords << 2) * height) <= GP3_BLT_1PASS_SIZE && (gp3_cmd_bottom - gp3_cmd_current) > (GP3_BLT_1PASS_SIZE + 72)) { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + ((total_dwords << 2) * height) + 8; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | (total_dwords * height)); while (height--) { /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); srcoffset += pitch; cim_cmd_ptr += total_dwords << 2; } WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } else { /* WRITE DATA LINE BY LINE * Each line will be created as a separate command buffer entry to * allow line-by-line wrapping and to allow simultaneous rendering * by the HW. */ while (height--) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoffset += pitch; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } } } /*--------------------------------------------------------------------------- * gp_custom_convert_blt * * This routine is identical to gp_color_convert_blt, except that the macro * to write data to the frame buffer has been replaced with a new macro. This * allows a user to implement custom behavior when sending data, such as * manually converting 24BPP to 32BPP, converting 2BPP to 4BPP or * premultiplying alpha data. *-------------------------------------------------------------------------*/ void gp_custom_convert_blt(unsigned long dstoffset, unsigned long srcx, unsigned long width, unsigned long height, unsigned char *data, long pitch) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long size = ((width << 16) | height); unsigned long ch3_offset, srcoffset; unsigned long ch3_size, base; /* ASSUME BITMAPS ARE DWORD ALIGNED */ /* We will offset into the source data in DWORD increments. We */ /* set the source index to the remaining byte offset and */ /* increment the size of each line to account for the dont-care */ /* pixel(s). For 4BPP source data, we also set the appropriate */ /* nibble index. */ /* CALCULATE THE SIZE OF ONE LINE */ if ((gp3_src_format & GP3_CH3_SRC_MASK) == GP3_CH3_SRC_24BPP_PACKED) { /* HANDLE 24BPP * Note that we do not do anything to guarantee that the source data * is DWORD aligned. The logic here is that the source data will be * cacheable, in which case Geode LX will not lose any clocks for * unaligned moves. Also note that the channel 3 width is programmed * as the number of dwords, while the normal width is programmed as * the number of pixels. */ srcoffset = srcx * 3; ch3_offset = 0; temp = width * 3; ch3_size = (((temp + 3) >> 2) << 16) | height; } else { ch3_size = size; if (gp3_src_pix_shift == 3) { /* CALCULATE INDENT AND SOURCE OFFSET */ indent = (srcx >> 1); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent | ((srcx & 1) << 25); temp = ((width + (srcx & 1) + 1) >> 1) + indent; } else { indent = (srcx << gp3_src_pix_shift); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent; temp = (width << gp3_src_pix_shift) + indent; } } total_dwords = (temp + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (temp >> 2); byte_count = (temp & 3); base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); /* SET APPROPRIATE ENABLES */ gp3_cmd_header |= GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF) | gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, ch3_offset); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, ch3_size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_HST_SRC_ENABLE | gp3_src_format | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; if (((total_dwords << 2) * height) <= GP3_BLT_1PASS_SIZE && (gp3_cmd_bottom - gp3_cmd_current) > (GP3_BLT_1PASS_SIZE + 72)) { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + ((total_dwords << 2) * height) + 8; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | (total_dwords * height)); while (height--) { /* WRITE DATA */ WRITE_CUSTOM_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_CUSTOM_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); srcoffset += pitch; cim_cmd_ptr += total_dwords << 2; } WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } else { /* WRITE DATA LINE BY LINE * Each line will be created as a separate command buffer entry to * allow line-by-line wrapping and to allow simultaneous rendering * by the HW. */ while (height--) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_CUSTOM_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_CUSTOM_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoffset += pitch; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } } } /*--------------------------------------------------------------------------- * gp_rotate_blt * * This routine is called to rotate a rectangular area of video memory. The * data may be color converted during the rotation. 'Degrees' must be a * multiple of 90 and indicates a clockwise rotation. Width and height * refer to the width and the height of the source. The output * destinations will be equal to the rotated dimensions. *-------------------------------------------------------------------------*/ void gp_rotate_blt(unsigned long dstoffset, unsigned long srcoffset, unsigned long width, unsigned long height, int degrees) { unsigned long sizein, sizeout; unsigned long ch3_flags; unsigned long base; base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | ((gp3_fb_base << 4) + ((srcoffset & 0xFFC00000) >> 20)) | (gp3_base_register & GP3_BASE_OFFSET_SRCMASK); srcoffset &= 0x3FFFFF; dstoffset &= 0x3FFFFF; /* SET ROTATION PARAMETERS */ switch (degrees) { case 90: srcoffset += (height - 1) * gp3_src_stride; sizein = ((width << 16) | height); sizeout = ((height << 16) | width); ch3_flags = GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_ROTATE_ENABLE | GP3_CH3_NEG_YDIR; break; case 180: srcoffset += (height - 1) * gp3_src_stride; srcoffset += (width << gp3_src_pix_shift) - 1; sizein = sizeout = ((width << 16) | height); ch3_flags = GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_NEG_YDIR | GP3_CH3_NEG_XDIR; break; case 270: srcoffset += (width << gp3_src_pix_shift) - 1; sizein = ((width << 16) | height); sizeout = ((height << 16) | width); ch3_flags = GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_ROTATE_ENABLE | GP3_CH3_NEG_XDIR; break; default: sizein = sizeout = ((width << 16) | height); ch3_flags = GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE; break; } /* SET APPROPRIATE ENABLES */ /* We override the raster mode setting with a source */ /* copy ROP. */ gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* WRITE ALL BLT REGISTERS */ WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | 0xCC); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoffset); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, sizeout); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, sizein); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, srcoffset); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, ch3_flags | gp3_src_format | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20) | ((gp3_blt_flags & CIMGP_ENABLE_PREFETCH) << 17) | gp3_src_stride); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_mono_bitmap_to_screen_blt * * This routine expands and BLTs a monchrome bitmap that is stored in system * memory into the framebuffer. 'data' points to an array of monochrome data. * 'stride' indicates the pitch between successive lines of monochrome data. * 'srcx' indicates the x coordinate within each line of blend data * corresponding to the first pixel. A y coordinate for the source is * deliberately omitted to avoid extra calculation for simple cases that have * no y index. The calling program must adjust the data pointer accordingly. *-------------------------------------------------------------------------*/ void gp_mono_bitmap_to_screen_blt(unsigned long dstoffset, unsigned long srcx, unsigned long width, unsigned long height, unsigned char *data, long stride) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long size = ((width << 16) | height); unsigned long srcoffset, src_value; /* ASSUME BITMAPS ARE DWORD ALIGNED */ /* We will offset into the source data in DWORD increments. We */ /* set the source index to the remaining byte offset and */ /* increment the size of each line to account for the dont-care */ /* pixel(s). */ indent = (srcx >> 3); srcoffset = (indent & ~3L); indent &= 3; src_value = (indent | ((srcx & 7) << 26)); /* PROGRAM THE NORMAL SOURCE CHANNEL REGISTERS */ /* We assume that a color pattern is being ROPed with source */ /* data if the pattern type is color and the preserve pattern */ /* was set. */ gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; if (gp3_ch3_pat) { gp3_cmd_header |= GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, gp3_pat_format); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); } else { WRITE_COMMAND32(GP3_BLT_DST_OFFSET, ((dstoffset & 0x3FFFFF) | gp3_pat_origin)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, 0); } if (gp3_blt_flags & CIMGP_BLTFLAGS_INVERTMONO) { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode | GP3_RM_SOURCE_INVERT); } else { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode & ~GP3_RM_SOURCE_INVERT); } WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, src_value); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000))); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode | GP3_BM_SRC_HOST | GP3_BM_SRC_MONO); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* CALCULATE THE SIZE OF ONE LINE */ size = ((width + (srcx & 7) + 7) >> 3) + indent; total_dwords = (size + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (size >> 2); byte_count = (size & 3); /* CHECK FOR SMALL BLT CASE */ /* If the total amount of monochrome data is less than 50K and we have */ /* room in the command buffer, we will do all data writes in a single */ /* data packet. */ if (((total_dwords << 2) * height) <= GP3_BLT_1PASS_SIZE && (gp3_cmd_bottom - gp3_cmd_current) > (GP3_BLT_1PASS_SIZE + 72)) { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + ((total_dwords << 2) * height) + 8; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_HOST_SOURCE_TYPE | (total_dwords * height)); while (height--) { /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); srcoffset += stride; cim_cmd_ptr += total_dwords << 2; } WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } else { /* WRITE DATA LINE BY LINE * Each line will be created as a separate command buffer entry to * allow line-by-line wrapping and to allow simultaneous rendering * by the HW. */ while (height--) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoffset += stride; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } } } /*--------------------------------------------------------------------------- * gp_text_blt * * This routine expands and BLTs byte-packed monochrome data to the screen. * There is assumed to be no x clipping involved in the BLT. *-------------------------------------------------------------------------*/ void gp_text_blt(unsigned long dstoffset, unsigned long width, unsigned long height, unsigned char *data) { unsigned long temp, dwords_total; unsigned long dword_count, byte_count; unsigned long size = ((width << 16) | height); unsigned long srcoffset = 0; /* PROGRAM THE NORMAL SOURCE CHANNEL REGISTERS */ /* We assume that a color pattern is being ROPed with source */ /* data if the pattern type is color and the preserve pattern */ /* was set. */ gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; if (gp3_ch3_pat) { gp3_cmd_header |= GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, gp3_pat_format); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); } else { WRITE_COMMAND32(GP3_BLT_DST_OFFSET, ((dstoffset & 0x3FFFFF) | gp3_pat_origin)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, 0); } if (gp3_blt_flags & CIMGP_BLTFLAGS_INVERTMONO) { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode | GP3_RM_SOURCE_INVERT); } else { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode & ~GP3_RM_SOURCE_INVERT); } WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, 0); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000))); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode | GP3_BM_SRC_HOST | GP3_BM_SRC_BP_MONO); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* CALCULATE THE TOTAL NUMBER OF BYTES */ size = ((width + 7) >> 3) * height; /* WRITE ALL DATA IN CHUNKS */ do { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; if (size > 8192) { dword_count = 2048; byte_count = 0; dwords_total = 2048; size -= 8192; } else { dword_count = (size >> 2); byte_count = (size & 3); dwords_total = (size + 3) >> 2; size = 0; } gp3_cmd_next = gp3_cmd_current + (dwords_total << 2) + 8; /* CHECK IF A WRAP WILL BE NEEDED */ if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_HOST_SOURCE_TYPE | dwords_total); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* UPDATE THE SOURCE OFFSET */ /* We add a constant value because the code will loop only if the */ /* data exceeds 8192 bytes. */ srcoffset += 8192; } while (size); } /*--------------------------------------------------------------------------- * gp_mono_expand_blt * * This routine expands monochrome data that is stored in video memory into * the current BPP. The source and destination regions are assumed not to * overlap. The pitch of the source data is specified in gp_set_strides. * 'srcy' is deliberately omitted to prevent extra calculations for simple * applications that have no source indexes. *-------------------------------------------------------------------------*/ void gp_mono_expand_blt(unsigned long dstoffset, unsigned long srcoffset, unsigned long srcx, unsigned long width, unsigned long height, int byte_packed) { unsigned long base; unsigned long blt_mode; unsigned long size = ((width << 16) | height); /* ADJUST SOURCE OFFSET */ srcoffset += (srcx >> 3); srcx &= 7; /* CALCULATE BASE OFFSET REGISTER */ base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | ((gp3_fb_base << 14) + ((srcoffset & 0xFFC00000) >> 10)) | (gp3_base_register & GP3_BASE_OFFSET_CH3MASK); /* SET THE SOURCE TYPE */ if (byte_packed) blt_mode = gp3_blt_mode | GP3_BM_SRC_FB | GP3_BM_SRC_BP_MONO; else blt_mode = gp3_blt_mode | GP3_BM_SRC_FB | GP3_BM_SRC_MONO; /* SET HEADER ENABLES */ gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* ENABLE COLOR PATTERN IF APPLICABLE */ if (gp3_ch3_pat) { gp3_cmd_header |= GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, gp3_pat_origin); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, gp3_pat_format); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); } else { WRITE_COMMAND32(GP3_BLT_DST_OFFSET, ((dstoffset & 0x3FFFFF) | gp3_pat_origin)); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, 0); } if (gp3_blt_flags & CIMGP_BLTFLAGS_INVERTMONO) { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode | GP3_RM_SOURCE_INVERT); } else { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_raster_mode & ~GP3_RM_SOURCE_INVERT); } WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, (srcoffset & 0x3FFFFF) | (srcx << 26)); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); /* WORKAROUND FOR SIBZ #3744 * Under extremely rare conditions, very narrow byte-packed mono BLTs * can hang the GP. Even under the rare case, the bad condition will * only happen once every 16 lines. The workaround is to break the * offending BLT into a series of safer BLTs. This method is preferred * over a two-pass approach because it does not require saving and * restoring any GP state, such as the ROP or mono colors. */ if ((gp3_blt_mode & GP3_BM_DST_REQ) && byte_packed && (gp3_pix_shift < 2) && (width < 5) && ((srcoffset & 0x1F) == 0x1F) && ((srcx + width) > 8)) { unsigned long dstoff1, size1, org1; unsigned long dstoff2, size2, org2; unsigned long tempheight; size1 = ((8 - srcx) << 16) | 1; size2 = ((width + srcx - 8) << 16) | 1; org1 = gp3_pat_origin; org2 = (org1 & 0xE0000000) | ((org1 + ((8 - srcx) << 26)) & 0x1C000000); dstoff1 = dstoffset & 0x3FFFFF; dstoff2 = (dstoff1 + 8 - srcx) << gp3_pix_shift; while (height) { /* DIVIDE THE FIRST LINE INTO TWO SINGLE LINE BLTS */ WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size1); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size1); WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, (srcoffset & 0x3FFFFF) | (srcx << 26)); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoff1 | org1); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, org1); WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; gp_wait_until_idle(); gp_declare_blt(gp3_blt_flags); gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size2); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size2); WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, ((srcoffset + 1) & 0x3FFFFF)); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoff2 | org2); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, org2); WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; gp_wait_until_idle(); if (--height) { org1 += 0x20000000; org2 += 0x20000000; dstoff1 += gp3_dst_stride; dstoff2 += gp3_dst_stride; srcoffset += 2; /* THE NEXT 15 LINES ARE NOW 'SAFE' - THEY DO NOT SHOW THE * PROBLEM */ tempheight = 15; if (tempheight > height) tempheight = height; gp_declare_blt(gp3_blt_flags); gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, (width << 16) | tempheight); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, (width << 16) | tempheight); WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, (srcoffset & 0x3FFFFF) | (srcx << 26)); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoff1 | org1); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, org1); WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; gp_wait_until_idle(); height -= tempheight; if (height) { gp_declare_blt(gp3_blt_flags); gp3_cmd_header |= GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE; /* ADJUST ORIGIN */ /* If we get here, we added a full 15 lines which is * equivalent to subtracting one from the pattern y origin * (adding 15). */ org1 -= 0x20000000; org2 -= 0x20000000; dstoff1 += (gp3_dst_stride * 15); dstoff2 += (gp3_dst_stride * 15); srcoffset += 30; } } } return; } /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_BLT_MODE, blt_mode); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_antialiased_text * * This routine implements alpha blending between a constant source color and * a destination region. The degree of the blend is controlled by an array * of 4BPP/8BPP values specified in 'data'. 'stride' indicates the pitch * between successive lines of blend data. 'srcx' indicates the x * coordinate within each line of blend data corresponding to the first * pixel. A y coordinate for the source is deliberately omitted to avoid * extra calculation for simple cases that have no y index. The calling * program must adjust the data pointer accordingly. 'fourbpp' selects * between 4BPP and 8BPP alpha. *-------------------------------------------------------------------------*/ void gp_antialiased_text(unsigned long dstoffset, unsigned long srcx, unsigned long width, unsigned long height, unsigned char *data, long stride, int fourbpp) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long size = ((width << 16) | height); unsigned long ch3_offset, srcoffset; unsigned long base, depth_flag; base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); /* ENABLE ALL RELEVANT REGISTERS */ /* We override the raster mode register to force the */ /* correct alpha blend */ gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* CALCULATIONS BASED ON ALPHA DEPTH */ /* Although most antialiased text is 4BPP, the hardware supports */ /* a full 8BPP. Either case is supported by this routine. */ if (fourbpp) { depth_flag = GP3_CH3_SRC_4BPP_ALPHA; indent = (srcx >> 1); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent | ((srcx & 1) << 25); temp = ((width + (srcx & 1) + 1) >> 1) + indent; } else { depth_flag = GP3_CH3_SRC_8BPP_ALPHA; indent = srcx; srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent; temp = width + indent; } total_dwords = (temp + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (temp >> 2); byte_count = (temp & 3); /* SET RASTER MODE REGISTER */ /* Alpha blending will only apply to RGB when no alpha component is present. */ /* As 8BPP is not supported for this routine, the only alpha-less mode is */ /* 5:6:5. */ if (gp3_bpp == GP3_RM_BPPFMT_565) { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | GP3_RM_ALPHA_TO_RGB | GP3_RM_ALPHA_A_PLUS_BETA_B | GP3_RM_SELECT_ALPHA_CHAN_3); } else { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | GP3_RM_ALPHA_ALL | GP3_RM_ALPHA_A_PLUS_BETA_B | GP3_RM_SELECT_ALPHA_CHAN_3); } /* WRITE ALL REMAINING REGISTERS */ WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF)); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, ch3_offset); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_HST_SRC_ENABLE | depth_flag | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode | GP3_BM_DST_REQ); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* WRITE DATA LINE BY LINE * Each line will be created as a separate command buffer entry to allow * line-by-line wrapping and to allow simultaneous rendering by the HW. */ if (((total_dwords << 2) * height) <= GP3_BLT_1PASS_SIZE && (gp3_cmd_bottom - gp3_cmd_current) > (GP3_BLT_1PASS_SIZE + 72)) { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + ((total_dwords << 2) * height) + 8; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | (total_dwords * height)); while (height--) { /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); srcoffset += stride; cim_cmd_ptr += total_dwords << 2; } WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } else { while (height--) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), data, srcoffset + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoffset += stride; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } } } /*--------------------------------------------------------------------------- * gp_masked_blt * * This routine copies source data to the screen. A monochrome mask is used * to specify source transparency. *-------------------------------------------------------------------------*/ void gp_masked_blt(unsigned long dstoffset, unsigned long width, unsigned long height, unsigned long mono_srcx, unsigned long color_srcx, unsigned char *mono_mask, unsigned char *color_data, long mono_pitch, long color_pitch) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long srcoffset, size; unsigned long j, ch3_offset, base; unsigned long flags = 0; if (gp3_blt_flags & CIMGP_BLTFLAGS_INVERTMONO) flags = GP3_RM_SOURCE_INVERT; /* MONO CALCULATIONS */ indent = (mono_srcx >> 3); srcoffset = (indent & ~3L); indent &= 3; size = ((width + (mono_srcx & 7) + 7) >> 3) + indent; total_dwords = (size + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (size >> 2); byte_count = (size & 3); base = ((gp3_fb_base << 24) + (gp3_scratch_base & 0xFFC00000)) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_STRIDE_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; WRITE_COMMAND32(GP3_BLT_RASTER_MODE, GP3_RM_BPPFMT_8888 | 0xCC); WRITE_COMMAND32(GP3_BLT_STRIDE, (total_dwords << 2)); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, gp3_scratch_base & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, (total_dwords << 16) | height); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, (total_dwords << 16) | height); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, 0); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_HST_SRC_ENABLE | GP3_CH3_SRC_8_8_8_8 | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, 0); WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); /* START THE BLT */ WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; for (j = 0; j < height; j++) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, mono_mask, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), mono_mask, srcoffset + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoffset += mono_pitch; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /* SECOND BLT */ gp_declare_blt(gp3_blt_flags | CIMGP_BLTFLAGS_HAZARD); base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | ((gp3_fb_base << 14) + (((gp3_scratch_base + indent) & 0xFFC00000) >> 10)) | (gp3_base_register & GP3_BASE_OFFSET_CH3MASK); gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_STRIDE_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* ENABLE TRANSPARENCY AND PATTERN COPY ROP * The monochrome data is used as a mask but is otherwise not involved in * the BLT. The color data is routed through the pattern channel. */ WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | 0xF0 | GP3_RM_SRC_TRANS | flags); WRITE_COMMAND32(GP3_BLT_STRIDE, (total_dwords << 18) | gp3_dst_stride); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoffset & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, ((gp3_scratch_base + indent) & 0x3FFFFF) | ((mono_srcx & 7) << 26)); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, (width << 16) | height); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, (width << 16) | height); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); /* PROGRAM PARAMETERS FOR COLOR SOURCE DATA */ /* Data may be color converted along the way. */ if ((gp3_src_format & GP3_CH3_SRC_MASK) == GP3_CH3_SRC_24BPP_PACKED) { srcoffset = color_srcx * 3; ch3_offset = 0; size = width * 3; WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, (((size + 3) >> 2) << 16) | height); } else if (gp3_src_pix_shift == 3) { /* CALCULATE INDENT AND SOURCE OFFSET */ indent = (color_srcx >> 1); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent | ((color_srcx & 1) << 25); size = ((width + (color_srcx & 1) + 1) >> 1) + indent; } else { indent = (color_srcx << gp3_src_pix_shift); srcoffset = (indent & ~3L); indent &= 3; ch3_offset = indent; size = (width << gp3_src_pix_shift) + indent; } total_dwords = (size + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (size >> 2); byte_count = (size & 3); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, ch3_offset); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_HST_SRC_ENABLE | gp3_src_format | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode | GP3_BM_SRC_MONO | GP3_BM_SRC_FB); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* WRITE DATA LINE BY LINE */ while (height--) { /* UPDATE THE COMMAND POINTER */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | total_dwords); /* WRITE COLOR DATA TO THE COMMAND BUFFER */ WRITE_COMMAND_STRING32(8, color_data, srcoffset, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), color_data, srcoffset + (dword_count << 2), byte_count); /* UPDATE COMMAND BUFFER POINTERS */ /* We do this before writing the monochrome data because otherwise */ /* the GP could throttle the writes to the host source register */ /* waiting for color data. If the command buffer has not been */ /* updated to load the color data... */ srcoffset += color_pitch; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } } /*--------------------------------------------------------------------------- * gp_screen_to_screen_masked * * This routine performs a screen to screen BLT, using a monochrome mask to * specify source transparency. The source data is assumed to be in the * current destination format and to not overlap the destination. *-------------------------------------------------------------------------*/ void gp_screen_to_screen_masked(unsigned long dstoffset, unsigned long srcoffset, unsigned long width, unsigned long height, unsigned long mono_srcx, unsigned char *mono_mask, long mono_pitch) { unsigned long indent, temp; unsigned long total_dwords, size_dwords; unsigned long dword_count, byte_count; unsigned long srcoff, size; unsigned long j, base; unsigned long flags = 0; if (gp3_blt_flags & CIMGP_BLTFLAGS_INVERTMONO) flags = GP3_RM_SOURCE_INVERT; /* MONO CALCULATIONS */ indent = (mono_srcx >> 3); srcoff = (indent & ~3L); indent &= 3; size = ((width + (mono_srcx & 7) + 7) >> 3) + indent; total_dwords = (size + 3) >> 2; size_dwords = (total_dwords << 2) + 8; dword_count = (size >> 2); byte_count = (size & 3); base = ((gp3_fb_base << 24) + (gp3_scratch_base & 0xFFC00000)) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_STRIDE_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; WRITE_COMMAND32(GP3_BLT_RASTER_MODE, GP3_RM_BPPFMT_8888 | 0xCC); WRITE_COMMAND32(GP3_BLT_STRIDE, (total_dwords << 2)); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, gp3_scratch_base & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, (total_dwords << 16) | height); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, (total_dwords << 16) | height); WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, 0); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_HST_SRC_ENABLE | GP3_CH3_SRC_8_8_8_8 | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, 0); WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); /* START THE BLT */ WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; for (j = 0; j < height; j++) { /* UPDATE THE COMMAND POINTER * The WRITE_COMMANDXX macros use a pointer to the current buffer * space. This is created by adding gp3_cmd_current to the base * pointer. */ cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; /* CHECK IF A WRAP WILL BE NEEDED */ gp3_cmd_next = gp3_cmd_current + size_dwords; if ((gp3_cmd_bottom - gp3_cmd_next) <= GP3_MAX_COMMAND_SIZE) { gp3_cmd_next = gp3_cmd_top; /* WAIT FOR HARDWARE */ GP3_WAIT_WRAP(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_WRAP | GP3_DATA_LOAD_HDR_ENABLE); } else { /* WAIT FOR AVAILABLE SPACE */ GP3_WAIT_PRIMITIVE(temp); WRITE_COMMAND32(0, GP3_DATA_LOAD_HDR_TYPE | GP3_DATA_LOAD_HDR_ENABLE); } /* WRITE DWORD COUNT */ WRITE_COMMAND32(4, GP3_CH3_HOST_SOURCE_TYPE | total_dwords); /* WRITE DATA */ WRITE_COMMAND_STRING32(8, mono_mask, srcoff, dword_count); WRITE_COMMAND_STRING8(8 + (dword_count << 2), mono_mask, srcoff + (dword_count << 2), byte_count); /* UPDATE POINTERS */ srcoff += mono_pitch; WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /* SECOND BLT */ gp_declare_blt(gp3_blt_flags | CIMGP_BLTFLAGS_HAZARD); base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | ((gp3_fb_base << 14) + (((gp3_scratch_base + indent) & 0xFFC00000) >> 10)) | ((gp3_fb_base << 4) + ((srcoffset & 0xFFC00000) >> 20)); gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_STRIDE_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_SRC_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* ENABLE TRANSPARENCY AND PATTERN COPY ROP * The monochrome data is used as a mask but is otherwise not involved * in the BLT. The color data is routed through the pattern channel. */ WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | 0xF0 | GP3_RM_SRC_TRANS | flags); WRITE_COMMAND32(GP3_BLT_STRIDE, (total_dwords << 18) | gp3_dst_stride); WRITE_COMMAND32(GP3_BLT_DST_OFFSET, dstoffset & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_SRC_OFFSET, ((gp3_scratch_base + indent) & 0x3FFFFF) | ((mono_srcx & 7) << 26)); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, (width << 16) | height); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, (width << 16) | height); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); /* PROGRAM PARAMETERS FOR COLOR SOURCE DATA */ WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, srcoffset & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | gp3_ch3_bpp | gp3_src_stride | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, gp3_blt_mode | GP3_BM_SRC_MONO | GP3_BM_SRC_FB); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; } /*--------------------------------------------------------------------------- * gp_bresenham_line * * This routine draws a vector using the specified Bresenham parameters. * Currently this file does not support a routine that accepts the two * endpoints of a vector and calculates the Bresenham parameters. If it * ever does, this routine is still required for vectors that have been * clipped. *-------------------------------------------------------------------------*/ void gp_bresenham_line(unsigned long dstoffset, unsigned short length, unsigned short initerr, unsigned short axialerr, unsigned short diagerr, unsigned long flags) { unsigned long base; long offset; /* HANDLE NEGATIVE VECTORS */ /* We have to be very careful with vectors that increment negatively */ /* Our framebuffer scheme tries to align the destination of every */ /* BLT or vector to the nearest 4MB-aligned boundary. This is */ /* necessary because the GP only supports offsets up to 16MB, but the */ /* framebuffer can be over 128MB. To solve this problem, the GP */ /* base address registers are alignable to 4MB regions. However, we */ /* cannot simply align the dest offset when the vector goes negative. */ /* The vector offset could underflow, causing the offset to jump from */ /* near 0 to 16MB. As we cannot accurately determine the last address */ /* that will be written in a vector short of walking the algorithm in */ /* software, we do a worst case approximation. */ offset = dstoffset; if (!(flags & CIMGP_POSMAJOR)) { if (flags & CIMGP_YMAJOR) offset -= length * gp3_dst_stride; else offset -= (length << gp3_pix_shift); if (offset < 0) offset = 0; } if (!(flags & CIMGP_POSMINOR)) { if (flags & CIMGP_YMAJOR) offset -= (length << gp3_pix_shift); else offset -= length * gp3_dst_stride; if (offset < 0) offset = 0; } offset &= 0xFFC00000; dstoffset -= offset; base = ((gp3_fb_base << 24) + offset) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); /* ENABLE RELEVANT REGISTERS */ /* Note that we always enable and write the channel 3 mode, if only */ /* to turn it off. Cimarron also always writes the base offset */ /* register to allow operation with frame buffers larger than 16MB. */ gp3_cmd_header |= GP3_VEC_HDR_DST_OFF_ENABLE | GP3_VEC_HDR_VEC_ERR_ENABLE | GP3_VEC_HDR_VEC_LEN_ENABLE | GP3_VEC_HDR_BASE_OFFSET_ENABLE | GP3_VEC_HDR_CH3_STR_ENABLE | GP3_VEC_HDR_VEC_MODE_ENABLE; /* WRITE THE REGISTERS COMMON TO ALL PATTERN TYPES */ /* The destination base is the frame buffer base plus whatever */ /* 4MB segment we happen to be drawing to. */ WRITE_COMMAND32(GP3_VECTOR_VEC_ERR, (((unsigned long) axialerr << 16) | (unsigned long) diagerr)); WRITE_COMMAND32(GP3_VECTOR_VEC_LEN, (((unsigned long) length << 16) | (unsigned long) initerr)); WRITE_COMMAND32(GP3_VECTOR_BASE_OFFSET, base); /* CHECK VECTOR PATTERN CASE */ if (gp3_ch3_pat) { /* SET THE SOLID COLOR */ /* The color for vector patterns from channel 3 comes from */ /* the regular pattern registers. */ gp3_cmd_header |= GP3_VEC_HDR_PAT_CLR0_ENABLE; WRITE_COMMAND32(GP3_VECTOR_PAT_COLOR_0, gp3_vector_pattern_color); /* INITIALIZE CHANNEL 3 PARAMETERS * We route the channel 3 output to the old source channel. If the * user sets a ROP that involves source, they will get unexpected * results. */ WRITE_COMMAND32(GP3_VECTOR_DST_OFFSET, dstoffset); WRITE_COMMAND32(GP3_VECTOR_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_COLOR_PAT_ENABLE | GP3_CH3_SRC_8_8_8_8); } else { /* DISABLE CHANNEL 3 AND USE NORMAL PATTERN ORIGINS */ WRITE_COMMAND32(GP3_VECTOR_CH3_MODE_STR, 0); WRITE_COMMAND32(GP3_VECTOR_DST_OFFSET, (dstoffset | gp3_pat_origin)); } /* START THE VECTOR */ WRITE_COMMAND32(GP3_VEC_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_VECTOR_MODE, (gp3_vec_mode | flags)); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* ADD A SECOND VECTOR TO CLEAR THE BYTE ENABLES */ /* We set a transparent pattern to clear the byte enables. */ /* We then restore the previous pattern. (SiBZ #4001) */ if (gp3_ch3_pat) { cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; WRITE_COMMAND32(0, GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE); WRITE_COMMAND32(4, 0x100); WRITE_COMMAND32(8, (1 | GP3_LUT_DATA_TYPE)); WRITE_COMMAND32(12, 0); /* DUMMY VECTOR */ /* We shouldn't need to write anything but vector mode and the length */ WRITE_COMMAND32(16, GP3_VEC_HDR_TYPE | GP3_VEC_HDR_VEC_MODE_ENABLE | GP3_VEC_HDR_VEC_LEN_ENABLE); WRITE_COMMAND32(16 + GP3_VECTOR_MODE, (gp3_vec_mode | flags)); WRITE_COMMAND32(16 + GP3_VECTOR_VEC_LEN, (1 << 16) | (unsigned long) initerr); WRITE_COMMAND32(16 + GP3_VECTOR_COMMAND_SIZE, GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE); WRITE_COMMAND32(20 + GP3_VECTOR_COMMAND_SIZE, 0x100); WRITE_COMMAND32(24 + GP3_VECTOR_COMMAND_SIZE, (1 | GP3_LUT_DATA_TYPE)); WRITE_COMMAND32(28 + GP3_VECTOR_COMMAND_SIZE, gp3_vec_pat); gp3_cmd_current += 32 + GP3_VECTOR_COMMAND_SIZE; } } /*--------------------------------------------------------------------------- * gp_line_from_endpoints * * This routine draws a vector from a set of rectangular coordinates. The * rectangle is assumed to use the currently specified destination stride. *-------------------------------------------------------------------------*/ void gp_line_from_endpoints(unsigned long dstoffset, unsigned long x0, unsigned long y0, unsigned long x1, unsigned long y1, int inclusive) { unsigned long base; unsigned long length; unsigned long flags; unsigned short initerr, axialerr, diagerr; long dx, dy, dmaj, dmin; long offset; /* ADJUST DESTINATION OFFSET BASED ON STARTING COORDINATE */ dstoffset += (x0 << gp3_pix_shift) + (y0 * gp3_dst_stride); /* CALCULATE BRESENHAM TERMS */ dx = (long) x1 - (long) x0; dy = (long) y1 - (long) y0; if (dx < 0) dx = -dx; if (dy < 0) dy = -dy; if (dx >= dy) { dmaj = dx; dmin = dy; flags = 0; if (x1 > x0) flags |= CIMGP_POSMAJOR; if (y1 > y0) flags |= CIMGP_POSMINOR; } else { dmaj = dy; dmin = dx; flags = CIMGP_YMAJOR; if (x1 > x0) flags |= CIMGP_POSMINOR; if (y1 > y0) flags |= CIMGP_POSMAJOR; } axialerr = (unsigned short) (dmin << 1); diagerr = (unsigned short) ((dmin - dmaj) << 1); initerr = (unsigned short) ((dmin << 1) - dmaj); if (!(flags & CIMGP_POSMINOR)) initerr--; /* CHECK FOR NO WORK */ if (!dmaj) return; /* CHECK INCLUSIVE OR EXCLUSIVE */ /* An inclusive line can be accomplished by simply adding 1 to the */ /* line length. */ length = dmaj; if (inclusive) length++; /* HANDLE NEGATIVE VECTORS */ offset = dstoffset; if (!(flags & CIMGP_POSMAJOR)) { if (flags & CIMGP_YMAJOR) offset -= length * gp3_dst_stride; else offset -= (length << gp3_pix_shift); if (offset < 0) offset = 0; } if (!(flags & CIMGP_POSMINOR)) { if (flags & CIMGP_YMAJOR) offset -= (length << gp3_pix_shift); else offset -= length * gp3_dst_stride; if (offset < 0) offset = 0; } offset &= 0xFFC00000; dstoffset -= offset; base = ((gp3_fb_base << 24) + offset) | (gp3_base_register & ~GP3_BASE_OFFSET_DSTMASK); /* ENABLE RELEVANT REGISTERS */ /* Note that we always enable and write the channel 3 mode, if only */ /* to turn it off. Cimarron also always writes the base offset */ /* register to allow operation with frame buffers larger than 16MB. */ gp3_cmd_header |= GP3_VEC_HDR_DST_OFF_ENABLE | GP3_VEC_HDR_VEC_ERR_ENABLE | GP3_VEC_HDR_VEC_LEN_ENABLE | GP3_VEC_HDR_BASE_OFFSET_ENABLE | GP3_VEC_HDR_CH3_STR_ENABLE | GP3_VEC_HDR_VEC_MODE_ENABLE; /* WRITE THE REGISTERS COMMON TO ALL PATTERN TYPES */ /* The destination base is the frame buffer base plus whatever */ /* 4MB segment we happen to be drawing to. */ WRITE_COMMAND32(GP3_VECTOR_VEC_ERR, (((unsigned long) axialerr << 16) | (unsigned long) diagerr)); WRITE_COMMAND32(GP3_VECTOR_VEC_LEN, (((unsigned long) length << 16) | (unsigned long) initerr)); WRITE_COMMAND32(GP3_VECTOR_BASE_OFFSET, base); /* CHECK VECTOR PATTERN CASE */ if (gp3_ch3_pat) { /* SET THE SOLID COLOR */ /* The color for vector patterns from channel 3 comes from */ /* the regular pattern registers. */ gp3_cmd_header |= GP3_VEC_HDR_PAT_CLR0_ENABLE; WRITE_COMMAND32(GP3_VECTOR_PAT_COLOR_0, gp3_vector_pattern_color); /* INITIALIZE CHANNEL 3 PARAMETERS */ /* We route the channel 3 output to the old source channel. If the * user sets a ROP that involves source, they will get unexpected * results. */ WRITE_COMMAND32(GP3_VECTOR_DST_OFFSET, dstoffset); WRITE_COMMAND32(GP3_VECTOR_CH3_MODE_STR, GP3_CH3_C3EN | GP3_CH3_REPLACE_SOURCE | GP3_CH3_COLOR_PAT_ENABLE | GP3_CH3_SRC_8_8_8_8); } else { /* DISABLE CHANNEL 3 AND USE NORMAL PATTERN ORIGINS */ WRITE_COMMAND32(GP3_VECTOR_CH3_MODE_STR, 0); WRITE_COMMAND32(GP3_VECTOR_DST_OFFSET, (dstoffset | gp3_pat_origin)); } /* START THE VECTOR */ WRITE_COMMAND32(GP3_VEC_CMD_HEADER, gp3_cmd_header); WRITE_COMMAND32(GP3_VECTOR_MODE, (gp3_vec_mode | flags)); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; /* ADD A SECOND VECTOR TO CLEAR THE BYTE ENABLES */ /* We set a transparent pattern to clear the byte enables. */ /* We then restore the previous pattern. (SiBZ #4001) */ if (gp3_ch3_pat) { cim_cmd_ptr = cim_cmd_base_ptr + gp3_cmd_current; WRITE_COMMAND32(0, GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE); WRITE_COMMAND32(4, 0x100); WRITE_COMMAND32(8, (1 | GP3_LUT_DATA_TYPE)); WRITE_COMMAND32(12, 0); /* DUMMY VECTOR */ /* We shouldn't need to write anything but vector mode and the length */ WRITE_COMMAND32(16, GP3_VEC_HDR_TYPE | GP3_VEC_HDR_VEC_MODE_ENABLE | GP3_VEC_HDR_VEC_LEN_ENABLE); WRITE_COMMAND32(16 + GP3_VECTOR_MODE, (gp3_vec_mode | flags)); WRITE_COMMAND32(16 + GP3_VECTOR_VEC_LEN, (1 << 16) | (unsigned long) initerr); WRITE_COMMAND32(16 + GP3_VECTOR_COMMAND_SIZE, GP3_LUT_HDR_TYPE | GP3_LUT_HDR_DATA_ENABLE); WRITE_COMMAND32(20 + GP3_VECTOR_COMMAND_SIZE, 0x100); WRITE_COMMAND32(24 + GP3_VECTOR_COMMAND_SIZE, (1 | GP3_LUT_DATA_TYPE)); WRITE_COMMAND32(28 + GP3_VECTOR_COMMAND_SIZE, gp3_vec_pat); gp3_cmd_current += 32 + GP3_VECTOR_COMMAND_SIZE; } } /*--------------------------------------------------------------------------- * gp_wait_until_idle * * This routine stalls execution until the GP is no longer actively rendering. *-------------------------------------------------------------------------*/ void gp_wait_until_idle(void) { unsigned long temp; while (((temp = READ_GP32(GP3_BLT_STATUS)) & GP3_BS_BLT_BUSY) || !(temp & GP3_BS_CB_EMPTY)) { ; } } /*--------------------------------------------------------------------------- * gp_test_blt_busy *-------------------------------------------------------------------------*/ int gp_test_blt_busy(void) { unsigned long temp; if (((temp = READ_GP32(GP3_BLT_STATUS)) & GP3_BS_BLT_BUSY) || !(temp & GP3_BS_CB_EMPTY)) return 1; return 0; } /*--------------------------------------------------------------------------- * gp_test_blt_pending *-------------------------------------------------------------------------*/ int gp_test_blt_pending(void) { if ((READ_GP32(GP3_BLT_STATUS)) & GP3_BS_BLT_PENDING) return 1; return 0; } /*--------------------------------------------------------------------------- * gp_wait_blt_pending *-------------------------------------------------------------------------*/ void gp_wait_blt_pending(void) { while ((READ_GP32(GP3_BLT_STATUS)) & GP3_BS_BLT_PENDING); } /*--------------------------------------------------------------------------- * gp_save_state * * This routine saves all persistent GP information. *-------------------------------------------------------------------------*/ void gp_save_state(GP_SAVE_RESTORE *gp_state) { Q_WORD msr_value; gp_wait_until_idle(); msr_read64(MSR_DEVICE_GEODELX_GP, MSR_GEODELINK_CONFIG, &msr_value); gp_state->cmd_bottom = READ_GP32(GP3_CMD_BOT) & 0xFFFFFF; gp_state->cmd_top = READ_GP32(GP3_CMD_TOP) & 0xFFFFFF; gp_state->cmd_base = (msr_value.low << 4) & 0xFFF00000; gp_state->base_offset = READ_GP32(GP3_BASE_OFFSET); /* RESET THE READ POINTER */ gp_set_command_buffer_base(gp_state->cmd_base, gp_state->cmd_top, gp_state->cmd_bottom); } /*--------------------------------------------------------------------------- * gp_restore_state * * This routine restores all persistent GP information. *-------------------------------------------------------------------------*/ void gp_restore_state(GP_SAVE_RESTORE *gp_state) { gp_wait_until_idle(); WRITE_GP32(GP3_BASE_OFFSET, gp_state->base_offset); gp_set_command_buffer_base(gp_state->cmd_base, gp_state->cmd_top, gp_state->cmd_bottom); } /* This is identical to gp_antialiased_text, except we support all one pass alpha operations similar to gp_set_alpha_operation */ void gp_blend_mask_blt(unsigned long dstoffset, unsigned long srcx, unsigned long width, unsigned long height, unsigned long dataoffset, long stride, int operation, int fourbpp) { unsigned long indent; unsigned long size = ((width << 16) | height); unsigned long base, depth_flag; base = ((gp3_fb_base << 24) + (dstoffset & 0xFFC00000)) | ((gp3_fb_base << 4) + (dataoffset >> 20)) | (gp3_base_register & GP3_BASE_OFFSET_SRCMASK); /* ENABLE ALL RELEVANT REGISTERS */ /* We override the raster mode register to force the */ /* correct alpha blend */ gp3_cmd_header |= GP3_BLT_HDR_RASTER_ENABLE | GP3_BLT_HDR_DST_OFF_ENABLE | GP3_BLT_HDR_WIDHI_ENABLE | GP3_BLT_HDR_CH3_OFF_ENABLE | GP3_BLT_HDR_CH3_STR_ENABLE | GP3_BLT_HDR_CH3_WIDHI_ENABLE | GP3_BLT_HDR_BASE_OFFSET_ENABLE | GP3_BLT_HDR_BLT_MODE_ENABLE; /* CALCULATIONS BASED ON ALPHA DEPTH */ /* Although most antialiased text is 4BPP, the hardware supports */ /* a full 8BPP. Either case is supported by this routine. */ if (fourbpp) { depth_flag = GP3_CH3_SRC_4BPP_ALPHA; indent = (srcx >> 1) & 3; dataoffset += indent | ((srcx & 1) << 25); } else { depth_flag = GP3_CH3_SRC_8BPP_ALPHA; indent = srcx & 3; dataoffset += indent; } /* SET RASTER MODE REGISTER */ /* Alpha blending will only apply to RGB when no alpha component is present. */ /* As 8BPP is not supported for this routine, the only alpha-less mode is */ /* 5:6:5. */ if (gp3_bpp == GP3_RM_BPPFMT_565) { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | GP3_RM_ALPHA_TO_RGB | ((unsigned long) (operation << 20)) | GP3_RM_SELECT_ALPHA_CHAN_3); } else { WRITE_COMMAND32(GP3_BLT_RASTER_MODE, gp3_bpp | GP3_RM_ALPHA_ALL | ((unsigned long) (operation << 20)) | GP3_RM_SELECT_ALPHA_CHAN_3); } /* WRITE ALL REMAINING REGISTERS */ WRITE_COMMAND32(GP3_BLT_DST_OFFSET, (dstoffset & 0x3FFFFF)); /* Set the offset of the CH3 data in memory */ WRITE_COMMAND32(GP3_BLT_CH3_OFFSET, dataoffset & 0x3FFFFF); WRITE_COMMAND32(GP3_BLT_WID_HEIGHT, size); WRITE_COMMAND32(GP3_BLT_CH3_WIDHI, size); WRITE_COMMAND32(GP3_BLT_BASE_OFFSET, base); WRITE_COMMAND32(GP3_BLT_CH3_MODE_STR, GP3_CH3_C3EN | (stride & 0xFFFF) | depth_flag | ((gp3_blt_flags & CIMGP_BLTFLAGS_PRES_LUT) << 20)); WRITE_COMMAND32(GP3_BLT_MODE, GP3_BM_DST_REQ); /* START THE BLT */ WRITE_COMMAND32(GP3_BLT_CMD_HEADER, gp3_cmd_header); WRITE_GP32(GP3_CMD_WRITE, gp3_cmd_next); gp3_cmd_current = gp3_cmd_next; }