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gfiber / kernel / windcharger / d95f9bd73fd3a4ebabf7c524941f6b6095388c55 / . / drivers / gpu / drm / radeon / r100.c
blob: 68e728e8be4d3cda06ca678a5c363fd95a94eb84 [file] [log] [blame]
/*
* Copyright 2008 Advanced Micro Devices, Inc.
* Copyright 2008 Red Hat Inc.
* Copyright 2009 Jerome Glisse.
*
* 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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.
*
* Authors: Dave Airlie
* Alex Deucher
* Jerome Glisse
*/
#include <linux/seq_file.h>
#include "drmP.h"
#include "drm.h"
#include "radeon_drm.h"
#include "radeon_microcode.h"
#include "radeon_reg.h"
#include "radeon.h"
/* This files gather functions specifics to:
* r100,rv100,rs100,rv200,rs200,r200,rv250,rs300,rv280
*
* Some of these functions might be used by newer ASICs.
*/
void r100_hdp_reset(struct radeon_device *rdev);
void r100_gpu_init(struct radeon_device *rdev);
int r100_gui_wait_for_idle(struct radeon_device *rdev);
int r100_mc_wait_for_idle(struct radeon_device *rdev);
void r100_gpu_wait_for_vsync(struct radeon_device *rdev);
void r100_gpu_wait_for_vsync2(struct radeon_device *rdev);
int r100_debugfs_mc_info_init(struct radeon_device *rdev);
/*
* PCI GART
*/
void r100_pci_gart_tlb_flush(struct radeon_device *rdev)
{
/* TODO: can we do somethings here ? */
/* It seems hw only cache one entry so we should discard this
* entry otherwise if first GPU GART read hit this entry it
* could end up in wrong address. */
}
int r100_pci_gart_enable(struct radeon_device *rdev)
{
uint32_t tmp;
int r;
/* Initialize common gart structure */
r = radeon_gart_init(rdev);
if (r) {
return r;
}
if (rdev->gart.table.ram.ptr == NULL) {
rdev->gart.table_size = rdev->gart.num_gpu_pages * 4;
r = radeon_gart_table_ram_alloc(rdev);
if (r) {
return r;
}
}
/* discard memory request outside of configured range */
tmp = RREG32(RADEON_AIC_CNTL) | RADEON_DIS_OUT_OF_PCI_GART_ACCESS;
WREG32(RADEON_AIC_CNTL, tmp);
/* set address range for PCI address translate */
WREG32(RADEON_AIC_LO_ADDR, rdev->mc.gtt_location);
tmp = rdev->mc.gtt_location + rdev->mc.gtt_size - 1;
WREG32(RADEON_AIC_HI_ADDR, tmp);
/* Enable bus mastering */
tmp = RREG32(RADEON_BUS_CNTL) & ~RADEON_BUS_MASTER_DIS;
WREG32(RADEON_BUS_CNTL, tmp);
/* set PCI GART page-table base address */
WREG32(RADEON_AIC_PT_BASE, rdev->gart.table_addr);
tmp = RREG32(RADEON_AIC_CNTL) | RADEON_PCIGART_TRANSLATE_EN;
WREG32(RADEON_AIC_CNTL, tmp);
r100_pci_gart_tlb_flush(rdev);
rdev->gart.ready = true;
return 0;
}
void r100_pci_gart_disable(struct radeon_device *rdev)
{
uint32_t tmp;
/* discard memory request outside of configured range */
tmp = RREG32(RADEON_AIC_CNTL) | RADEON_DIS_OUT_OF_PCI_GART_ACCESS;
WREG32(RADEON_AIC_CNTL, tmp & ~RADEON_PCIGART_TRANSLATE_EN);
WREG32(RADEON_AIC_LO_ADDR, 0);
WREG32(RADEON_AIC_HI_ADDR, 0);
}
int r100_pci_gart_set_page(struct radeon_device *rdev, int i, uint64_t addr)
{
if (i < 0 || i > rdev->gart.num_gpu_pages) {
return -EINVAL;
}
rdev->gart.table.ram.ptr[i] = cpu_to_le32(lower_32_bits(addr));
return 0;
}
int r100_gart_enable(struct radeon_device *rdev)
{
if (rdev->flags & RADEON_IS_AGP) {
r100_pci_gart_disable(rdev);
return 0;
}
return r100_pci_gart_enable(rdev);
}
/*
* MC
*/
void r100_mc_disable_clients(struct radeon_device *rdev)
{
uint32_t ov0_scale_cntl, crtc_ext_cntl, crtc_gen_cntl, crtc2_gen_cntl;
/* FIXME: is this function correct for rs100,rs200,rs300 ? */
if (r100_gui_wait_for_idle(rdev)) {
printk(KERN_WARNING "Failed to wait GUI idle while "
"programming pipes. Bad things might happen.\n");
}
/* stop display and memory access */
ov0_scale_cntl = RREG32(RADEON_OV0_SCALE_CNTL);
WREG32(RADEON_OV0_SCALE_CNTL, ov0_scale_cntl & ~RADEON_SCALER_ENABLE);
crtc_ext_cntl = RREG32(RADEON_CRTC_EXT_CNTL);
WREG32(RADEON_CRTC_EXT_CNTL, crtc_ext_cntl | RADEON_CRTC_DISPLAY_DIS);
crtc_gen_cntl = RREG32(RADEON_CRTC_GEN_CNTL);
r100_gpu_wait_for_vsync(rdev);
WREG32(RADEON_CRTC_GEN_CNTL,
(crtc_gen_cntl & ~(RADEON_CRTC_CUR_EN | RADEON_CRTC_ICON_EN)) |
RADEON_CRTC_DISP_REQ_EN_B | RADEON_CRTC_EXT_DISP_EN);
if (!(rdev->flags & RADEON_SINGLE_CRTC)) {
crtc2_gen_cntl = RREG32(RADEON_CRTC2_GEN_CNTL);
r100_gpu_wait_for_vsync2(rdev);
WREG32(RADEON_CRTC2_GEN_CNTL,
(crtc2_gen_cntl &
~(RADEON_CRTC2_CUR_EN | RADEON_CRTC2_ICON_EN)) |
RADEON_CRTC2_DISP_REQ_EN_B);
}
udelay(500);
}
void r100_mc_setup(struct radeon_device *rdev)
{
uint32_t tmp;
int r;
r = r100_debugfs_mc_info_init(rdev);
if (r) {
DRM_ERROR("Failed to register debugfs file for R100 MC !\n");
}
/* Write VRAM size in case we are limiting it */
WREG32(RADEON_CONFIG_MEMSIZE, rdev->mc.real_vram_size);
/* Novell bug 204882 for RN50/M6/M7 with 8/16/32MB VRAM,
* if the aperture is 64MB but we have 32MB VRAM
* we report only 32MB VRAM but we have to set MC_FB_LOCATION
* to 64MB, otherwise the gpu accidentially dies */
tmp = rdev->mc.vram_location + rdev->mc.mc_vram_size - 1;
tmp = REG_SET(RADEON_MC_FB_TOP, tmp >> 16);
tmp |= REG_SET(RADEON_MC_FB_START, rdev->mc.vram_location >> 16);
WREG32(RADEON_MC_FB_LOCATION, tmp);
/* Enable bus mastering */
tmp = RREG32(RADEON_BUS_CNTL) & ~RADEON_BUS_MASTER_DIS;
WREG32(RADEON_BUS_CNTL, tmp);
if (rdev->flags & RADEON_IS_AGP) {
tmp = rdev->mc.gtt_location + rdev->mc.gtt_size - 1;
tmp = REG_SET(RADEON_MC_AGP_TOP, tmp >> 16);
tmp |= REG_SET(RADEON_MC_AGP_START, rdev->mc.gtt_location >> 16);
WREG32(RADEON_MC_AGP_LOCATION, tmp);
WREG32(RADEON_AGP_BASE, rdev->mc.agp_base);
} else {
WREG32(RADEON_MC_AGP_LOCATION, 0x0FFFFFFF);
WREG32(RADEON_AGP_BASE, 0);
}
tmp = RREG32(RADEON_HOST_PATH_CNTL) & RADEON_HDP_APER_CNTL;
tmp |= (7 << 28);
WREG32(RADEON_HOST_PATH_CNTL, tmp | RADEON_HDP_SOFT_RESET | RADEON_HDP_READ_BUFFER_INVALIDATE);
(void)RREG32(RADEON_HOST_PATH_CNTL);
WREG32(RADEON_HOST_PATH_CNTL, tmp);
(void)RREG32(RADEON_HOST_PATH_CNTL);
}
int r100_mc_init(struct radeon_device *rdev)
{
int r;
if (r100_debugfs_rbbm_init(rdev)) {
DRM_ERROR("Failed to register debugfs file for RBBM !\n");
}
r100_gpu_init(rdev);
/* Disable gart which also disable out of gart access */
r100_pci_gart_disable(rdev);
/* Setup GPU memory space */
rdev->mc.gtt_location = 0xFFFFFFFFUL;
if (rdev->flags & RADEON_IS_AGP) {
r = radeon_agp_init(rdev);
if (r) {
printk(KERN_WARNING "[drm] Disabling AGP\n");
rdev->flags &= ~RADEON_IS_AGP;
rdev->mc.gtt_size = radeon_gart_size * 1024 * 1024;
} else {
rdev->mc.gtt_location = rdev->mc.agp_base;
}
}
r = radeon_mc_setup(rdev);
if (r) {
return r;
}
r100_mc_disable_clients(rdev);
if (r100_mc_wait_for_idle(rdev)) {
printk(KERN_WARNING "Failed to wait MC idle while "
"programming pipes. Bad things might happen.\n");
}
r100_mc_setup(rdev);
return 0;
}
void r100_mc_fini(struct radeon_device *rdev)
{
r100_pci_gart_disable(rdev);
radeon_gart_table_ram_free(rdev);
radeon_gart_fini(rdev);
}
/*
* Interrupts
*/
int r100_irq_set(struct radeon_device *rdev)
{
uint32_t tmp = 0;
if (rdev->irq.sw_int) {
tmp |= RADEON_SW_INT_ENABLE;
}
if (rdev->irq.crtc_vblank_int[0]) {
tmp |= RADEON_CRTC_VBLANK_MASK;
}
if (rdev->irq.crtc_vblank_int[1]) {
tmp |= RADEON_CRTC2_VBLANK_MASK;
}
WREG32(RADEON_GEN_INT_CNTL, tmp);
return 0;
}
static inline uint32_t r100_irq_ack(struct radeon_device *rdev)
{
uint32_t irqs = RREG32(RADEON_GEN_INT_STATUS);
uint32_t irq_mask = RADEON_SW_INT_TEST | RADEON_CRTC_VBLANK_STAT |
RADEON_CRTC2_VBLANK_STAT;
if (irqs) {
WREG32(RADEON_GEN_INT_STATUS, irqs);
}
return irqs & irq_mask;
}
int r100_irq_process(struct radeon_device *rdev)
{
uint32_t status;
status = r100_irq_ack(rdev);
if (!status) {
return IRQ_NONE;
}
while (status) {
/* SW interrupt */
if (status & RADEON_SW_INT_TEST) {
radeon_fence_process(rdev);
}
/* Vertical blank interrupts */
if (status & RADEON_CRTC_VBLANK_STAT) {
drm_handle_vblank(rdev->ddev, 0);
}
if (status & RADEON_CRTC2_VBLANK_STAT) {
drm_handle_vblank(rdev->ddev, 1);
}
status = r100_irq_ack(rdev);
}
return IRQ_HANDLED;
}
u32 r100_get_vblank_counter(struct radeon_device *rdev, int crtc)
{
if (crtc == 0)
return RREG32(RADEON_CRTC_CRNT_FRAME);
else
return RREG32(RADEON_CRTC2_CRNT_FRAME);
}
/*
* Fence emission
*/
void r100_fence_ring_emit(struct radeon_device *rdev,
struct radeon_fence *fence)
{
/* Who ever call radeon_fence_emit should call ring_lock and ask
* for enough space (today caller are ib schedule and buffer move) */
/* Wait until IDLE & CLEAN */
radeon_ring_write(rdev, PACKET0(0x1720, 0));
radeon_ring_write(rdev, (1 << 16) | (1 << 17));
/* Emit fence sequence & fire IRQ */
radeon_ring_write(rdev, PACKET0(rdev->fence_drv.scratch_reg, 0));
radeon_ring_write(rdev, fence->seq);
radeon_ring_write(rdev, PACKET0(RADEON_GEN_INT_STATUS, 0));
radeon_ring_write(rdev, RADEON_SW_INT_FIRE);
}
/*
* Writeback
*/
int r100_wb_init(struct radeon_device *rdev)
{
int r;
if (rdev->wb.wb_obj == NULL) {
r = radeon_object_create(rdev, NULL, 4096,
true,
RADEON_GEM_DOMAIN_GTT,
false, &rdev->wb.wb_obj);
if (r) {
DRM_ERROR("radeon: failed to create WB buffer (%d).\n", r);
return r;
}
r = radeon_object_pin(rdev->wb.wb_obj,
RADEON_GEM_DOMAIN_GTT,
&rdev->wb.gpu_addr);
if (r) {
DRM_ERROR("radeon: failed to pin WB buffer (%d).\n", r);
return r;
}
r = radeon_object_kmap(rdev->wb.wb_obj, (void **)&rdev->wb.wb);
if (r) {
DRM_ERROR("radeon: failed to map WB buffer (%d).\n", r);
return r;
}
}
WREG32(0x774, rdev->wb.gpu_addr);
WREG32(0x70C, rdev->wb.gpu_addr + 1024);
WREG32(0x770, 0xff);
return 0;
}
void r100_wb_fini(struct radeon_device *rdev)
{
if (rdev->wb.wb_obj) {
radeon_object_kunmap(rdev->wb.wb_obj);
radeon_object_unpin(rdev->wb.wb_obj);
radeon_object_unref(&rdev->wb.wb_obj);
rdev->wb.wb = NULL;
rdev->wb.wb_obj = NULL;
}
}
int r100_copy_blit(struct radeon_device *rdev,
uint64_t src_offset,
uint64_t dst_offset,
unsigned num_pages,
struct radeon_fence *fence)
{
uint32_t cur_pages;
uint32_t stride_bytes = PAGE_SIZE;
uint32_t pitch;
uint32_t stride_pixels;
unsigned ndw;
int num_loops;
int r = 0;
/* radeon limited to 16k stride */
stride_bytes &= 0x3fff;
/* radeon pitch is /64 */
pitch = stride_bytes / 64;
stride_pixels = stride_bytes / 4;
num_loops = DIV_ROUND_UP(num_pages, 8191);
/* Ask for enough room for blit + flush + fence */
ndw = 64 + (10 * num_loops);
r = radeon_ring_lock(rdev, ndw);
if (r) {
DRM_ERROR("radeon: moving bo (%d) asking for %u dw.\n", r, ndw);
return -EINVAL;
}
while (num_pages > 0) {
cur_pages = num_pages;
if (cur_pages > 8191) {
cur_pages = 8191;
}
num_pages -= cur_pages;
/* pages are in Y direction - height
page width in X direction - width */
radeon_ring_write(rdev, PACKET3(PACKET3_BITBLT_MULTI, 8));
radeon_ring_write(rdev,
RADEON_GMC_SRC_PITCH_OFFSET_CNTL |
RADEON_GMC_DST_PITCH_OFFSET_CNTL |
RADEON_GMC_SRC_CLIPPING |
RADEON_GMC_DST_CLIPPING |
RADEON_GMC_BRUSH_NONE |
(RADEON_COLOR_FORMAT_ARGB8888 << 8) |
RADEON_GMC_SRC_DATATYPE_COLOR |
RADEON_ROP3_S |
RADEON_DP_SRC_SOURCE_MEMORY |
RADEON_GMC_CLR_CMP_CNTL_DIS |
RADEON_GMC_WR_MSK_DIS);
radeon_ring_write(rdev, (pitch << 22) | (src_offset >> 10));
radeon_ring_write(rdev, (pitch << 22) | (dst_offset >> 10));
radeon_ring_write(rdev, (0x1fff) | (0x1fff << 16));
radeon_ring_write(rdev, 0);
radeon_ring_write(rdev, (0x1fff) | (0x1fff << 16));
radeon_ring_write(rdev, num_pages);
radeon_ring_write(rdev, num_pages);
radeon_ring_write(rdev, cur_pages | (stride_pixels << 16));
}
radeon_ring_write(rdev, PACKET0(RADEON_DSTCACHE_CTLSTAT, 0));
radeon_ring_write(rdev, RADEON_RB2D_DC_FLUSH_ALL);
radeon_ring_write(rdev, PACKET0(RADEON_WAIT_UNTIL, 0));
radeon_ring_write(rdev,
RADEON_WAIT_2D_IDLECLEAN |
RADEON_WAIT_HOST_IDLECLEAN |
RADEON_WAIT_DMA_GUI_IDLE);
if (fence) {
r = radeon_fence_emit(rdev, fence);
}
radeon_ring_unlock_commit(rdev);
return r;
}
/*
* CP
*/
void r100_ring_start(struct radeon_device *rdev)
{
int r;
r = radeon_ring_lock(rdev, 2);
if (r) {
return;
}
radeon_ring_write(rdev, PACKET0(RADEON_ISYNC_CNTL, 0));
radeon_ring_write(rdev,
RADEON_ISYNC_ANY2D_IDLE3D |
RADEON_ISYNC_ANY3D_IDLE2D |
RADEON_ISYNC_WAIT_IDLEGUI |
RADEON_ISYNC_CPSCRATCH_IDLEGUI);
radeon_ring_unlock_commit(rdev);
}
static void r100_cp_load_microcode(struct radeon_device *rdev)
{
int i;
if (r100_gui_wait_for_idle(rdev)) {
printk(KERN_WARNING "Failed to wait GUI idle while "
"programming pipes. Bad things might happen.\n");
}
WREG32(RADEON_CP_ME_RAM_ADDR, 0);
if ((rdev->family == CHIP_R100) || (rdev->family == CHIP_RV100) ||
(rdev->family == CHIP_RV200) || (rdev->family == CHIP_RS100) ||
(rdev->family == CHIP_RS200)) {
DRM_INFO("Loading R100 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, R100_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, R100_cp_microcode[i][0]);
}
} else if ((rdev->family == CHIP_R200) ||
(rdev->family == CHIP_RV250) ||
(rdev->family == CHIP_RV280) ||
(rdev->family == CHIP_RS300)) {
DRM_INFO("Loading R200 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, R200_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, R200_cp_microcode[i][0]);
}
} else if ((rdev->family == CHIP_R300) ||
(rdev->family == CHIP_R350) ||
(rdev->family == CHIP_RV350) ||
(rdev->family == CHIP_RV380) ||
(rdev->family == CHIP_RS400) ||
(rdev->family == CHIP_RS480)) {
DRM_INFO("Loading R300 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, R300_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, R300_cp_microcode[i][0]);
}
} else if ((rdev->family == CHIP_R420) ||
(rdev->family == CHIP_R423) ||
(rdev->family == CHIP_RV410)) {
DRM_INFO("Loading R400 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, R420_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, R420_cp_microcode[i][0]);
}
} else if ((rdev->family == CHIP_RS690) ||
(rdev->family == CHIP_RS740)) {
DRM_INFO("Loading RS690/RS740 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, RS690_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, RS690_cp_microcode[i][0]);
}
} else if (rdev->family == CHIP_RS600) {
DRM_INFO("Loading RS600 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, RS600_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, RS600_cp_microcode[i][0]);
}
} else if ((rdev->family == CHIP_RV515) ||
(rdev->family == CHIP_R520) ||
(rdev->family == CHIP_RV530) ||
(rdev->family == CHIP_R580) ||
(rdev->family == CHIP_RV560) ||
(rdev->family == CHIP_RV570)) {
DRM_INFO("Loading R500 Microcode\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_ME_RAM_DATAH, R520_cp_microcode[i][1]);
WREG32(RADEON_CP_ME_RAM_DATAL, R520_cp_microcode[i][0]);
}
}
}
int r100_cp_init(struct radeon_device *rdev, unsigned ring_size)
{
unsigned rb_bufsz;
unsigned rb_blksz;
unsigned max_fetch;
unsigned pre_write_timer;
unsigned pre_write_limit;
unsigned indirect2_start;
unsigned indirect1_start;
uint32_t tmp;
int r;
if (r100_debugfs_cp_init(rdev)) {
DRM_ERROR("Failed to register debugfs file for CP !\n");
}
/* Reset CP */
tmp = RREG32(RADEON_CP_CSQ_STAT);
if ((tmp & (1 << 31))) {
DRM_INFO("radeon: cp busy (0x%08X) resetting\n", tmp);
WREG32(RADEON_CP_CSQ_MODE, 0);
WREG32(RADEON_CP_CSQ_CNTL, 0);
WREG32(RADEON_RBBM_SOFT_RESET, RADEON_SOFT_RESET_CP);
tmp = RREG32(RADEON_RBBM_SOFT_RESET);
mdelay(2);
WREG32(RADEON_RBBM_SOFT_RESET, 0);
tmp = RREG32(RADEON_RBBM_SOFT_RESET);
mdelay(2);
tmp = RREG32(RADEON_CP_CSQ_STAT);
if ((tmp & (1 << 31))) {
DRM_INFO("radeon: cp reset failed (0x%08X)\n", tmp);
}
} else {
DRM_INFO("radeon: cp idle (0x%08X)\n", tmp);
}
/* Align ring size */
rb_bufsz = drm_order(ring_size / 8);
ring_size = (1 << (rb_bufsz + 1)) * 4;
r100_cp_load_microcode(rdev);
r = radeon_ring_init(rdev, ring_size);
if (r) {
return r;
}
/* Each time the cp read 1024 bytes (16 dword/quadword) update
* the rptr copy in system ram */
rb_blksz = 9;
/* cp will read 128bytes at a time (4 dwords) */
max_fetch = 1;
rdev->cp.align_mask = 16 - 1;
/* Write to CP_RB_WPTR will be delayed for pre_write_timer clocks */
pre_write_timer = 64;
/* Force CP_RB_WPTR write if written more than one time before the
* delay expire
*/
pre_write_limit = 0;
/* Setup the cp cache like this (cache size is 96 dwords) :
* RING 0 to 15
* INDIRECT1 16 to 79
* INDIRECT2 80 to 95
* So ring cache size is 16dwords (> (2 * max_fetch = 2 * 4dwords))
* indirect1 cache size is 64dwords (> (2 * max_fetch = 2 * 4dwords))
* indirect2 cache size is 16dwords (> (2 * max_fetch = 2 * 4dwords))
* Idea being that most of the gpu cmd will be through indirect1 buffer
* so it gets the bigger cache.
*/
indirect2_start = 80;
indirect1_start = 16;
/* cp setup */
WREG32(0x718, pre_write_timer | (pre_write_limit << 28));
WREG32(RADEON_CP_RB_CNTL,
#ifdef __BIG_ENDIAN
RADEON_BUF_SWAP_32BIT |
#endif
REG_SET(RADEON_RB_BUFSZ, rb_bufsz) |
REG_SET(RADEON_RB_BLKSZ, rb_blksz) |
REG_SET(RADEON_MAX_FETCH, max_fetch) |
RADEON_RB_NO_UPDATE);
/* Set ring address */
DRM_INFO("radeon: ring at 0x%016lX\n", (unsigned long)rdev->cp.gpu_addr);
WREG32(RADEON_CP_RB_BASE, rdev->cp.gpu_addr);
/* Force read & write ptr to 0 */
tmp = RREG32(RADEON_CP_RB_CNTL);
WREG32(RADEON_CP_RB_CNTL, tmp | RADEON_RB_RPTR_WR_ENA);
WREG32(RADEON_CP_RB_RPTR_WR, 0);
WREG32(RADEON_CP_RB_WPTR, 0);
WREG32(RADEON_CP_RB_CNTL, tmp);
udelay(10);
rdev->cp.rptr = RREG32(RADEON_CP_RB_RPTR);
rdev->cp.wptr = RREG32(RADEON_CP_RB_WPTR);
/* Set cp mode to bus mastering & enable cp*/
WREG32(RADEON_CP_CSQ_MODE,
REG_SET(RADEON_INDIRECT2_START, indirect2_start) |
REG_SET(RADEON_INDIRECT1_START, indirect1_start));
WREG32(0x718, 0);
WREG32(0x744, 0x00004D4D);
WREG32(RADEON_CP_CSQ_CNTL, RADEON_CSQ_PRIBM_INDBM);
radeon_ring_start(rdev);
r = radeon_ring_test(rdev);
if (r) {
DRM_ERROR("radeon: cp isn't working (%d).\n", r);
return r;
}
rdev->cp.ready = true;
return 0;
}
void r100_cp_fini(struct radeon_device *rdev)
{
/* Disable ring */
rdev->cp.ready = false;
WREG32(RADEON_CP_CSQ_CNTL, 0);
radeon_ring_fini(rdev);
DRM_INFO("radeon: cp finalized\n");
}
void r100_cp_disable(struct radeon_device *rdev)
{
/* Disable ring */
rdev->cp.ready = false;
WREG32(RADEON_CP_CSQ_MODE, 0);
WREG32(RADEON_CP_CSQ_CNTL, 0);
if (r100_gui_wait_for_idle(rdev)) {
printk(KERN_WARNING "Failed to wait GUI idle while "
"programming pipes. Bad things might happen.\n");
}
}
int r100_cp_reset(struct radeon_device *rdev)
{
uint32_t tmp;
bool reinit_cp;
int i;
reinit_cp = rdev->cp.ready;
rdev->cp.ready = false;
WREG32(RADEON_CP_CSQ_MODE, 0);
WREG32(RADEON_CP_CSQ_CNTL, 0);
WREG32(RADEON_RBBM_SOFT_RESET, RADEON_SOFT_RESET_CP);
(void)RREG32(RADEON_RBBM_SOFT_RESET);
udelay(200);
WREG32(RADEON_RBBM_SOFT_RESET, 0);
/* Wait to prevent race in RBBM_STATUS */
mdelay(1);
for (i = 0; i < rdev->usec_timeout; i++) {
tmp = RREG32(RADEON_RBBM_STATUS);
if (!(tmp & (1 << 16))) {
DRM_INFO("CP reset succeed (RBBM_STATUS=0x%08X)\n",
tmp);
if (reinit_cp) {
return r100_cp_init(rdev, rdev->cp.ring_size);
}
return 0;
}
DRM_UDELAY(1);
}
tmp = RREG32(RADEON_RBBM_STATUS);
DRM_ERROR("Failed to reset CP (RBBM_STATUS=0x%08X)!\n", tmp);
return -1;
}
/*
* CS functions
*/
int r100_cs_parse_packet0(struct radeon_cs_parser *p,
struct radeon_cs_packet *pkt,
const unsigned *auth, unsigned n,
radeon_packet0_check_t check)
{
unsigned reg;
unsigned i, j, m;
unsigned idx;
int r;
idx = pkt->idx + 1;
reg = pkt->reg;
/* Check that register fall into register range
* determined by the number of entry (n) in the
* safe register bitmap.
*/
if (pkt->one_reg_wr) {
if ((reg >> 7) > n) {
return -EINVAL;
}
} else {
if (((reg + (pkt->count << 2)) >> 7) > n) {
return -EINVAL;
}
}
for (i = 0; i <= pkt->count; i++, idx++) {
j = (reg >> 7);
m = 1 << ((reg >> 2) & 31);
if (auth[j] & m) {
r = check(p, pkt, idx, reg);
if (r) {
return r;
}
}
if (pkt->one_reg_wr) {
if (!(auth[j] & m)) {
break;
}
} else {
reg += 4;
}
}
return 0;
}
void r100_cs_dump_packet(struct radeon_cs_parser *p,
struct radeon_cs_packet *pkt)
{
struct radeon_cs_chunk *ib_chunk;
volatile uint32_t *ib;
unsigned i;
unsigned idx;
ib = p->ib->ptr;
ib_chunk = &p->chunks[p->chunk_ib_idx];
idx = pkt->idx;
for (i = 0; i <= (pkt->count + 1); i++, idx++) {
DRM_INFO("ib[%d]=0x%08X\n", idx, ib[idx]);
}
}
/**
* r100_cs_packet_parse() - parse cp packet and point ib index to next packet
* @parser: parser structure holding parsing context.
* @pkt: where to store packet informations
*
* Assume that chunk_ib_index is properly set. Will return -EINVAL
* if packet is bigger than remaining ib size. or if packets is unknown.
**/
int r100_cs_packet_parse(struct radeon_cs_parser *p,
struct radeon_cs_packet *pkt,
unsigned idx)
{
struct radeon_cs_chunk *ib_chunk = &p->chunks[p->chunk_ib_idx];
uint32_t header;
if (idx >= ib_chunk->length_dw) {
DRM_ERROR("Can not parse packet at %d after CS end %d !\n",
idx, ib_chunk->length_dw);
return -EINVAL;
}
header = ib_chunk->kdata[idx];
pkt->idx = idx;
pkt->type = CP_PACKET_GET_TYPE(header);
pkt->count = CP_PACKET_GET_COUNT(header);
switch (pkt->type) {
case PACKET_TYPE0:
pkt->reg = CP_PACKET0_GET_REG(header);
pkt->one_reg_wr = CP_PACKET0_GET_ONE_REG_WR(header);
break;
case PACKET_TYPE3:
pkt->opcode = CP_PACKET3_GET_OPCODE(header);
break;
case PACKET_TYPE2:
pkt->count = -1;
break;
default:
DRM_ERROR("Unknown packet type %d at %d !\n", pkt->type, idx);
return -EINVAL;
}
if ((pkt->count + 1 + pkt->idx) >= ib_chunk->length_dw) {
DRM_ERROR("Packet (%d:%d:%d) end after CS buffer (%d) !\n",
pkt->idx, pkt->type, pkt->count, ib_chunk->length_dw);
return -EINVAL;
}
return 0;
}
/**
* r100_cs_packet_next_vline() - parse userspace VLINE packet
* @parser: parser structure holding parsing context.
*
* Userspace sends a special sequence for VLINE waits.
* PACKET0 - VLINE_START_END + value
* PACKET0 - WAIT_UNTIL +_value
* RELOC (P3) - crtc_id in reloc.
*
* This function parses this and relocates the VLINE START END
* and WAIT UNTIL packets to the correct crtc.
* It also detects a switched off crtc and nulls out the
* wait in that case.
*/
int r100_cs_packet_parse_vline(struct radeon_cs_parser *p)
{
struct radeon_cs_chunk *ib_chunk;
struct drm_mode_object *obj;
struct drm_crtc *crtc;
struct radeon_crtc *radeon_crtc;
struct radeon_cs_packet p3reloc, waitreloc;
int crtc_id;
int r;
uint32_t header, h_idx, reg;
ib_chunk = &p->chunks[p->chunk_ib_idx];
/* parse the wait until */
r = r100_cs_packet_parse(p, &waitreloc, p->idx);
if (r)
return r;
/* check its a wait until and only 1 count */
if (waitreloc.reg != RADEON_WAIT_UNTIL ||
waitreloc.count != 0) {
DRM_ERROR("vline wait had illegal wait until segment\n");
r = -EINVAL;
return r;
}
if (ib_chunk->kdata[waitreloc.idx + 1] != RADEON_WAIT_CRTC_VLINE) {
DRM_ERROR("vline wait had illegal wait until\n");
r = -EINVAL;
return r;
}
/* jump over the NOP */
r = r100_cs_packet_parse(p, &p3reloc, p->idx);
if (r)
return r;
h_idx = p->idx - 2;
p->idx += waitreloc.count;
p->idx += p3reloc.count;
header = ib_chunk->kdata[h_idx];
crtc_id = ib_chunk->kdata[h_idx + 5];
reg = ib_chunk->kdata[h_idx] >> 2;
mutex_lock(&p->rdev->ddev->mode_config.mutex);
obj = drm_mode_object_find(p->rdev->ddev, crtc_id, DRM_MODE_OBJECT_CRTC);
if (!obj) {
DRM_ERROR("cannot find crtc %d\n", crtc_id);
r = -EINVAL;
goto out;
}
crtc = obj_to_crtc(obj);
radeon_crtc = to_radeon_crtc(crtc);
crtc_id = radeon_crtc->crtc_id;
if (!crtc->enabled) {
/* if the CRTC isn't enabled - we need to nop out the wait until */
ib_chunk->kdata[h_idx + 2] = PACKET2(0);
ib_chunk->kdata[h_idx + 3] = PACKET2(0);
} else if (crtc_id == 1) {
switch (reg) {
case AVIVO_D1MODE_VLINE_START_END:
header &= R300_CP_PACKET0_REG_MASK;
header |= AVIVO_D2MODE_VLINE_START_END >> 2;
break;
case RADEON_CRTC_GUI_TRIG_VLINE:
header &= R300_CP_PACKET0_REG_MASK;
header |= RADEON_CRTC2_GUI_TRIG_VLINE >> 2;
break;
default:
DRM_ERROR("unknown crtc reloc\n");
r = -EINVAL;
goto out;
}
ib_chunk->kdata[h_idx] = header;
ib_chunk->kdata[h_idx + 3] |= RADEON_ENG_DISPLAY_SELECT_CRTC1;
}
out:
mutex_unlock(&p->rdev->ddev->mode_config.mutex);
return r;
}
/**
* r100_cs_packet_next_reloc() - parse next packet which should be reloc packet3
* @parser: parser structure holding parsing context.
* @data: pointer to relocation data
* @offset_start: starting offset
* @offset_mask: offset mask (to align start offset on)
* @reloc: reloc informations
*
* Check next packet is relocation packet3, do bo validation and compute
* GPU offset using the provided start.
**/
int r100_cs_packet_next_reloc(struct radeon_cs_parser *p,
struct radeon_cs_reloc **cs_reloc)
{
struct radeon_cs_chunk *ib_chunk;
struct radeon_cs_chunk *relocs_chunk;
struct radeon_cs_packet p3reloc;
unsigned idx;
int r;
if (p->chunk_relocs_idx == -1) {
DRM_ERROR("No relocation chunk !\n");
return -EINVAL;
}
*cs_reloc = NULL;
ib_chunk = &p->chunks[p->chunk_ib_idx];
relocs_chunk = &p->chunks[p->chunk_relocs_idx];
r = r100_cs_packet_parse(p, &p3reloc, p->idx);
if (r) {
return r;
}
p->idx += p3reloc.count + 2;
if (p3reloc.type != PACKET_TYPE3 || p3reloc.opcode != PACKET3_NOP) {
DRM_ERROR("No packet3 for relocation for packet at %d.\n",
p3reloc.idx);
r100_cs_dump_packet(p, &p3reloc);
return -EINVAL;
}
idx = ib_chunk->kdata[p3reloc.idx + 1];
if (idx >= relocs_chunk->length_dw) {
DRM_ERROR("Relocs at %d after relocations chunk end %d !\n",
idx, relocs_chunk->length_dw);
r100_cs_dump_packet(p, &p3reloc);
return -EINVAL;
}
/* FIXME: we assume reloc size is 4 dwords */
*cs_reloc = p->relocs_ptr[(idx / 4)];
return 0;
}
static int r100_packet0_check(struct radeon_cs_parser *p,
struct radeon_cs_packet *pkt)
{
struct radeon_cs_chunk *ib_chunk;
struct radeon_cs_reloc *reloc;
volatile uint32_t *ib;
uint32_t tmp;
unsigned reg;
unsigned i;
unsigned idx;
bool onereg;
int r;
u32 tile_flags = 0;
ib = p->ib->ptr;
ib_chunk = &p->chunks[p->chunk_ib_idx];
idx = pkt->idx + 1;
reg = pkt->reg;
onereg = false;
if (CP_PACKET0_GET_ONE_REG_WR(ib_chunk->kdata[pkt->idx])) {
onereg = true;
}
for (i = 0; i <= pkt->count; i++, idx++, reg += 4) {
switch (reg) {
case RADEON_CRTC_GUI_TRIG_VLINE:
r = r100_cs_packet_parse_vline(p);
if (r) {
DRM_ERROR("No reloc for ib[%d]=0x%04X\n",
idx, reg);
r100_cs_dump_packet(p, pkt);
return r;
}
break;
/* FIXME: only allow PACKET3 blit? easier to check for out of
* range access */
case RADEON_DST_PITCH_OFFSET:
case RADEON_SRC_PITCH_OFFSET:
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for ib[%d]=0x%04X\n",
idx, reg);
r100_cs_dump_packet(p, pkt);
return r;
}
tmp = ib_chunk->kdata[idx] & 0x003fffff;
tmp += (((u32)reloc->lobj.gpu_offset) >> 10);
if (reloc->lobj.tiling_flags & RADEON_TILING_MACRO)
tile_flags |= RADEON_DST_TILE_MACRO;
if (reloc->lobj.tiling_flags & RADEON_TILING_MICRO) {
if (reg == RADEON_SRC_PITCH_OFFSET) {
DRM_ERROR("Cannot src blit from microtiled surface\n");
r100_cs_dump_packet(p, pkt);
return -EINVAL;
}
tile_flags |= RADEON_DST_TILE_MICRO;
}
tmp |= tile_flags;
ib[idx] = (ib_chunk->kdata[idx] & 0x3fc00000) | tmp;
break;
case RADEON_RB3D_DEPTHOFFSET:
case RADEON_RB3D_COLOROFFSET:
case R300_RB3D_COLOROFFSET0:
case R300_ZB_DEPTHOFFSET:
case R200_PP_TXOFFSET_0:
case R200_PP_TXOFFSET_1:
case R200_PP_TXOFFSET_2:
case R200_PP_TXOFFSET_3:
case R200_PP_TXOFFSET_4:
case R200_PP_TXOFFSET_5:
case RADEON_PP_TXOFFSET_0:
case RADEON_PP_TXOFFSET_1:
case RADEON_PP_TXOFFSET_2:
case R300_TX_OFFSET_0:
case R300_TX_OFFSET_0+4:
case R300_TX_OFFSET_0+8:
case R300_TX_OFFSET_0+12:
case R300_TX_OFFSET_0+16:
case R300_TX_OFFSET_0+20:
case R300_TX_OFFSET_0+24:
case R300_TX_OFFSET_0+28:
case R300_TX_OFFSET_0+32:
case R300_TX_OFFSET_0+36:
case R300_TX_OFFSET_0+40:
case R300_TX_OFFSET_0+44:
case R300_TX_OFFSET_0+48:
case R300_TX_OFFSET_0+52:
case R300_TX_OFFSET_0+56:
case R300_TX_OFFSET_0+60:
/* rn50 has no 3D engine so fail on any 3d setup */
if (ASIC_IS_RN50(p->rdev)) {
DRM_ERROR("attempt to use RN50 3D engine failed\n");
return -EINVAL;
}
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for ib[%d]=0x%04X\n",
idx, reg);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx] = ib_chunk->kdata[idx] + ((u32)reloc->lobj.gpu_offset);
break;
case R300_RB3D_COLORPITCH0:
case RADEON_RB3D_COLORPITCH:
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for ib[%d]=0x%04X\n",
idx, reg);
r100_cs_dump_packet(p, pkt);
return r;
}
if (reloc->lobj.tiling_flags & RADEON_TILING_MACRO)
tile_flags |= RADEON_COLOR_TILE_ENABLE;
if (reloc->lobj.tiling_flags & RADEON_TILING_MICRO)
tile_flags |= RADEON_COLOR_MICROTILE_ENABLE;
tmp = ib_chunk->kdata[idx] & ~(0x7 << 16);
tmp |= tile_flags;
ib[idx] = tmp;
break;
case RADEON_RB3D_ZPASS_ADDR:
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for ib[%d]=0x%04X\n",
idx, reg);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx] = ib_chunk->kdata[idx] + ((u32)reloc->lobj.gpu_offset);
break;
default:
/* FIXME: we don't want to allow anyothers packet */
break;
}
if (onereg) {
/* FIXME: forbid onereg write to register on relocate */
break;
}
}
return 0;
}
int r100_cs_track_check_pkt3_indx_buffer(struct radeon_cs_parser *p,
struct radeon_cs_packet *pkt,
struct radeon_object *robj)
{
struct radeon_cs_chunk *ib_chunk;
unsigned idx;
ib_chunk = &p->chunks[p->chunk_ib_idx];
idx = pkt->idx + 1;
if ((ib_chunk->kdata[idx+2] + 1) > radeon_object_size(robj)) {
DRM_ERROR("[drm] Buffer too small for PACKET3 INDX_BUFFER "
"(need %u have %lu) !\n",
ib_chunk->kdata[idx+2] + 1,
radeon_object_size(robj));
return -EINVAL;
}
return 0;
}
static int r100_packet3_check(struct radeon_cs_parser *p,
struct radeon_cs_packet *pkt)
{
struct radeon_cs_chunk *ib_chunk;
struct radeon_cs_reloc *reloc;
unsigned idx;
unsigned i, c;
volatile uint32_t *ib;
int r;
ib = p->ib->ptr;
ib_chunk = &p->chunks[p->chunk_ib_idx];
idx = pkt->idx + 1;
switch (pkt->opcode) {
case PACKET3_3D_LOAD_VBPNTR:
c = ib_chunk->kdata[idx++];
for (i = 0; i < (c - 1); i += 2, idx += 3) {
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for packet3 %d\n",
pkt->opcode);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx+1] = ib_chunk->kdata[idx+1] + ((u32)reloc->lobj.gpu_offset);
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for packet3 %d\n",
pkt->opcode);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx+2] = ib_chunk->kdata[idx+2] + ((u32)reloc->lobj.gpu_offset);
}
if (c & 1) {
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for packet3 %d\n",
pkt->opcode);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx+1] = ib_chunk->kdata[idx+1] + ((u32)reloc->lobj.gpu_offset);
}
break;
case PACKET3_INDX_BUFFER:
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for packet3 %d\n", pkt->opcode);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx+1] = ib_chunk->kdata[idx+1] + ((u32)reloc->lobj.gpu_offset);
r = r100_cs_track_check_pkt3_indx_buffer(p, pkt, reloc->robj);
if (r) {
return r;
}
break;
case 0x23:
/* FIXME: cleanup */
/* 3D_RNDR_GEN_INDX_PRIM on r100/r200 */
r = r100_cs_packet_next_reloc(p, &reloc);
if (r) {
DRM_ERROR("No reloc for packet3 %d\n", pkt->opcode);
r100_cs_dump_packet(p, pkt);
return r;
}
ib[idx] = ib_chunk->kdata[idx] + ((u32)reloc->lobj.gpu_offset);
break;
case PACKET3_3D_DRAW_IMMD:
/* triggers drawing using in-packet vertex data */
case PACKET3_3D_DRAW_IMMD_2:
/* triggers drawing using in-packet vertex data */
case PACKET3_3D_DRAW_VBUF_2:
/* triggers drawing of vertex buffers setup elsewhere */
case PACKET3_3D_DRAW_INDX_2:
/* triggers drawing using indices to vertex buffer */
case PACKET3_3D_DRAW_VBUF:
/* triggers drawing of vertex buffers setup elsewhere */
case PACKET3_3D_DRAW_INDX:
/* triggers drawing using indices to vertex buffer */
case PACKET3_NOP:
break;
default:
DRM_ERROR("Packet3 opcode %x not supported\n", pkt->opcode);
return -EINVAL;
}
return 0;
}
int r100_cs_parse(struct radeon_cs_parser *p)
{
struct radeon_cs_packet pkt;
int r;
do {
r = r100_cs_packet_parse(p, &pkt, p->idx);
if (r) {
return r;
}
p->idx += pkt.count + 2;
switch (pkt.type) {
case PACKET_TYPE0:
r = r100_packet0_check(p, &pkt);
break;
case PACKET_TYPE2:
break;
case PACKET_TYPE3:
r = r100_packet3_check(p, &pkt);
break;
default:
DRM_ERROR("Unknown packet type %d !\n",
pkt.type);
return -EINVAL;
}
if (r) {
return r;
}
} while (p->idx < p->chunks[p->chunk_ib_idx].length_dw);
return 0;
}
/*
* Global GPU functions
*/
void r100_errata(struct radeon_device *rdev)
{
rdev->pll_errata = 0;
if (rdev->family == CHIP_RV200 || rdev->family == CHIP_RS200) {
rdev->pll_errata |= CHIP_ERRATA_PLL_DUMMYREADS;
}
if (rdev->family == CHIP_RV100 ||
rdev->family == CHIP_RS100 ||
rdev->family == CHIP_RS200) {
rdev->pll_errata |= CHIP_ERRATA_PLL_DELAY;
}
}
/* Wait for vertical sync on primary CRTC */
void r100_gpu_wait_for_vsync(struct radeon_device *rdev)
{
uint32_t crtc_gen_cntl, tmp;
int i;
crtc_gen_cntl = RREG32(RADEON_CRTC_GEN_CNTL);
if ((crtc_gen_cntl & RADEON_CRTC_DISP_REQ_EN_B) ||
!(crtc_gen_cntl & RADEON_CRTC_EN)) {
return;
}
/* Clear the CRTC_VBLANK_SAVE bit */
WREG32(RADEON_CRTC_STATUS, RADEON_CRTC_VBLANK_SAVE_CLEAR);
for (i = 0; i < rdev->usec_timeout; i++) {
tmp = RREG32(RADEON_CRTC_STATUS);
if (tmp & RADEON_CRTC_VBLANK_SAVE) {
return;
}
DRM_UDELAY(1);
}
}
/* Wait for vertical sync on secondary CRTC */
void r100_gpu_wait_for_vsync2(struct radeon_device *rdev)
{
uint32_t crtc2_gen_cntl, tmp;
int i;
crtc2_gen_cntl = RREG32(RADEON_CRTC2_GEN_CNTL);
if ((crtc2_gen_cntl & RADEON_CRTC2_DISP_REQ_EN_B) ||
!(crtc2_gen_cntl & RADEON_CRTC2_EN))
return;
/* Clear the CRTC_VBLANK_SAVE bit */
WREG32(RADEON_CRTC2_STATUS, RADEON_CRTC2_VBLANK_SAVE_CLEAR);
for (i = 0; i < rdev->usec_timeout; i++) {
tmp = RREG32(RADEON_CRTC2_STATUS);
if (tmp & RADEON_CRTC2_VBLANK_SAVE) {
return;
}
DRM_UDELAY(1);
}
}
int r100_rbbm_fifo_wait_for_entry(struct radeon_device *rdev, unsigned n)
{
unsigned i;
uint32_t tmp;
for (i = 0; i < rdev->usec_timeout; i++) {
tmp = RREG32(RADEON_RBBM_STATUS) & RADEON_RBBM_FIFOCNT_MASK;
if (tmp >= n) {
return 0;
}
DRM_UDELAY(1);
}
return -1;
}
int r100_gui_wait_for_idle(struct radeon_device *rdev)
{
unsigned i;
uint32_t tmp;
if (r100_rbbm_fifo_wait_for_entry(rdev, 64)) {
printk(KERN_WARNING "radeon: wait for empty RBBM fifo failed !"
" Bad things might happen.\n");
}
for (i = 0; i < rdev->usec_timeout; i++) {
tmp = RREG32(RADEON_RBBM_STATUS);
if (!(tmp & (1 << 31))) {
return 0;
}
DRM_UDELAY(1);
}
return -1;
}
int r100_mc_wait_for_idle(struct radeon_device *rdev)
{
unsigned i;
uint32_t tmp;
for (i = 0; i < rdev->usec_timeout; i++) {
/* read MC_STATUS */
tmp = RREG32(0x0150);
if (tmp & (1 << 2)) {
return 0;
}
DRM_UDELAY(1);
}
return -1;
}
void r100_gpu_init(struct radeon_device *rdev)
{
/* TODO: anythings to do here ? pipes ? */
r100_hdp_reset(rdev);
}
void r100_hdp_reset(struct radeon_device *rdev)
{
uint32_t tmp;
tmp = RREG32(RADEON_HOST_PATH_CNTL) & RADEON_HDP_APER_CNTL;
tmp |= (7 << 28);
WREG32(RADEON_HOST_PATH_CNTL, tmp | RADEON_HDP_SOFT_RESET | RADEON_HDP_READ_BUFFER_INVALIDATE);
(void)RREG32(RADEON_HOST_PATH_CNTL);
udelay(200);
WREG32(RADEON_RBBM_SOFT_RESET, 0);
WREG32(RADEON_HOST_PATH_CNTL, tmp);
(void)RREG32(RADEON_HOST_PATH_CNTL);
}
int r100_rb2d_reset(struct radeon_device *rdev)
{
uint32_t tmp;
int i;
WREG32(RADEON_RBBM_SOFT_RESET, RADEON_SOFT_RESET_E2);
(void)RREG32(RADEON_RBBM_SOFT_RESET);
udelay(200);
WREG32(RADEON_RBBM_SOFT_RESET, 0);
/* Wait to prevent race in RBBM_STATUS */
mdelay(1);
for (i = 0; i < rdev->usec_timeout; i++) {
tmp = RREG32(RADEON_RBBM_STATUS);
if (!(tmp & (1 << 26))) {
DRM_INFO("RB2D reset succeed (RBBM_STATUS=0x%08X)\n",
tmp);
return 0;
}
DRM_UDELAY(1);
}
tmp = RREG32(RADEON_RBBM_STATUS);
DRM_ERROR("Failed to reset RB2D (RBBM_STATUS=0x%08X)!\n", tmp);
return -1;
}
int r100_gpu_reset(struct radeon_device *rdev)
{
uint32_t status;
/* reset order likely matter */
status = RREG32(RADEON_RBBM_STATUS);
/* reset HDP */
r100_hdp_reset(rdev);
/* reset rb2d */
if (status & ((1 << 17) | (1 << 18) | (1 << 27))) {
r100_rb2d_reset(rdev);
}
/* TODO: reset 3D engine */
/* reset CP */
status = RREG32(RADEON_RBBM_STATUS);
if (status & (1 << 16)) {
r100_cp_reset(rdev);
}
/* Check if GPU is idle */
status = RREG32(RADEON_RBBM_STATUS);
if (status & (1 << 31)) {
DRM_ERROR("Failed to reset GPU (RBBM_STATUS=0x%08X)\n", status);
return -1;
}
DRM_INFO("GPU reset succeed (RBBM_STATUS=0x%08X)\n", status);
return 0;
}
/*
* VRAM info
*/
static void r100_vram_get_type(struct radeon_device *rdev)
{
uint32_t tmp;
rdev->mc.vram_is_ddr = false;
if (rdev->flags & RADEON_IS_IGP)
rdev->mc.vram_is_ddr = true;
else if (RREG32(RADEON_MEM_SDRAM_MODE_REG) & RADEON_MEM_CFG_TYPE_DDR)
rdev->mc.vram_is_ddr = true;
if ((rdev->family == CHIP_RV100) ||
(rdev->family == CHIP_RS100) ||
(rdev->family == CHIP_RS200)) {
tmp = RREG32(RADEON_MEM_CNTL);
if (tmp & RV100_HALF_MODE) {
rdev->mc.vram_width = 32;
} else {
rdev->mc.vram_width = 64;
}
if (rdev->flags & RADEON_SINGLE_CRTC) {
rdev->mc.vram_width /= 4;
rdev->mc.vram_is_ddr = true;
}
} else if (rdev->family <= CHIP_RV280) {
tmp = RREG32(RADEON_MEM_CNTL);
if (tmp & RADEON_MEM_NUM_CHANNELS_MASK) {
rdev->mc.vram_width = 128;
} else {
rdev->mc.vram_width = 64;
}
} else {
/* newer IGPs */
rdev->mc.vram_width = 128;
}
}
static u32 r100_get_accessible_vram(struct radeon_device *rdev)
{
u32 aper_size;
u8 byte;
aper_size = RREG32(RADEON_CONFIG_APER_SIZE);
/* Set HDP_APER_CNTL only on cards that are known not to be broken,
* that is has the 2nd generation multifunction PCI interface
*/
if (rdev->family == CHIP_RV280 ||
rdev->family >= CHIP_RV350) {
WREG32_P(RADEON_HOST_PATH_CNTL, RADEON_HDP_APER_CNTL,
~RADEON_HDP_APER_CNTL);
DRM_INFO("Generation 2 PCI interface, using max accessible memory\n");
return aper_size * 2;
}
/* Older cards have all sorts of funny issues to deal with. First
* check if it's a multifunction card by reading the PCI config
* header type... Limit those to one aperture size
*/
pci_read_config_byte(rdev->pdev, 0xe, &byte);
if (byte & 0x80) {
DRM_INFO("Generation 1 PCI interface in multifunction mode\n");
DRM_INFO("Limiting VRAM to one aperture\n");
return aper_size;
}
/* Single function older card. We read HDP_APER_CNTL to see how the BIOS
* have set it up. We don't write this as it's broken on some ASICs but
* we expect the BIOS to have done the right thing (might be too optimistic...)
*/
if (RREG32(RADEON_HOST_PATH_CNTL) & RADEON_HDP_APER_CNTL)
return aper_size * 2;
return aper_size;
}
void r100_vram_init_sizes(struct radeon_device *rdev)
{
u64 config_aper_size;
u32 accessible;
config_aper_size = RREG32(RADEON_CONFIG_APER_SIZE);
if (rdev->flags & RADEON_IS_IGP) {
uint32_t tom;
/* read NB_TOM to get the amount of ram stolen for the GPU */
tom = RREG32(RADEON_NB_TOM);
rdev->mc.real_vram_size = (((tom >> 16) - (tom & 0xffff) + 1) << 16);
/* for IGPs we need to keep VRAM where it was put by the BIOS */
rdev->mc.vram_location = (tom & 0xffff) << 16;
WREG32(RADEON_CONFIG_MEMSIZE, rdev->mc.real_vram_size);
rdev->mc.mc_vram_size = rdev->mc.real_vram_size;
} else {
rdev->mc.real_vram_size = RREG32(RADEON_CONFIG_MEMSIZE);
/* Some production boards of m6 will report 0
* if it's 8 MB
*/
if (rdev->mc.real_vram_size == 0) {
rdev->mc.real_vram_size = 8192 * 1024;
WREG32(RADEON_CONFIG_MEMSIZE, rdev->mc.real_vram_size);
}
/* let driver place VRAM */
rdev->mc.vram_location = 0xFFFFFFFFUL;
/* Fix for RN50, M6, M7 with 8/16/32(??) MBs of VRAM -
* Novell bug 204882 + along with lots of ubuntu ones */
if (config_aper_size > rdev->mc.real_vram_size)
rdev->mc.mc_vram_size = config_aper_size;
else
rdev->mc.mc_vram_size = rdev->mc.real_vram_size;
}
/* work out accessible VRAM */
accessible = r100_get_accessible_vram(rdev);
rdev->mc.aper_base = drm_get_resource_start(rdev->ddev, 0);
rdev->mc.aper_size = drm_get_resource_len(rdev->ddev, 0);
if (accessible > rdev->mc.aper_size)
accessible = rdev->mc.aper_size;
if (rdev->mc.mc_vram_size > rdev->mc.aper_size)
rdev->mc.mc_vram_size = rdev->mc.aper_size;
if (rdev->mc.real_vram_size > rdev->mc.aper_size)
rdev->mc.real_vram_size = rdev->mc.aper_size;
}
void r100_vram_info(struct radeon_device *rdev)
{
r100_vram_get_type(rdev);
r100_vram_init_sizes(rdev);
}
/*
* Indirect registers accessor
*/
void r100_pll_errata_after_index(struct radeon_device *rdev)
{
if (!(rdev->pll_errata & CHIP_ERRATA_PLL_DUMMYREADS)) {
return;
}
(void)RREG32(RADEON_CLOCK_CNTL_DATA);
(void)RREG32(RADEON_CRTC_GEN_CNTL);
}
static void r100_pll_errata_after_data(struct radeon_device *rdev)
{
/* This workarounds is necessary on RV100, RS100 and RS200 chips
* or the chip could hang on a subsequent access
*/
if (rdev->pll_errata & CHIP_ERRATA_PLL_DELAY) {
udelay(5000);
}
/* This function is required to workaround a hardware bug in some (all?)
* revisions of the R300. This workaround should be called after every
* CLOCK_CNTL_INDEX register access. If not, register reads afterward
* may not be correct.
*/
if (rdev->pll_errata & CHIP_ERRATA_R300_CG) {
uint32_t save, tmp;
save = RREG32(RADEON_CLOCK_CNTL_INDEX);
tmp = save & ~(0x3f | RADEON_PLL_WR_EN);
WREG32(RADEON_CLOCK_CNTL_INDEX, tmp);
tmp = RREG32(RADEON_CLOCK_CNTL_DATA);
WREG32(RADEON_CLOCK_CNTL_INDEX, save);
}
}
uint32_t r100_pll_rreg(struct radeon_device *rdev, uint32_t reg)
{
uint32_t data;
WREG8(RADEON_CLOCK_CNTL_INDEX, reg & 0x3f);
r100_pll_errata_after_index(rdev);
data = RREG32(RADEON_CLOCK_CNTL_DATA);
r100_pll_errata_after_data(rdev);
return data;
}
void r100_pll_wreg(struct radeon_device *rdev, uint32_t reg, uint32_t v)
{
WREG8(RADEON_CLOCK_CNTL_INDEX, ((reg & 0x3f) | RADEON_PLL_WR_EN));
r100_pll_errata_after_index(rdev);
WREG32(RADEON_CLOCK_CNTL_DATA, v);
r100_pll_errata_after_data(rdev);
}
int r100_init(struct radeon_device *rdev)
{
return 0;
}
/*
* Debugfs info
*/
#if defined(CONFIG_DEBUG_FS)
static int r100_debugfs_rbbm_info(struct seq_file *m, void *data)
{
struct drm_info_node *node = (struct drm_info_node *) m->private;
struct drm_device *dev = node->minor->dev;
struct radeon_device *rdev = dev->dev_private;
uint32_t reg, value;
unsigned i;
seq_printf(m, "RBBM_STATUS 0x%08x\n", RREG32(RADEON_RBBM_STATUS));
seq_printf(m, "RBBM_CMDFIFO_STAT 0x%08x\n", RREG32(0xE7C));
seq_printf(m, "CP_STAT 0x%08x\n", RREG32(RADEON_CP_STAT));
for (i = 0; i < 64; i++) {
WREG32(RADEON_RBBM_CMDFIFO_ADDR, i | 0x100);
reg = (RREG32(RADEON_RBBM_CMDFIFO_DATA) - 1) >> 2;
WREG32(RADEON_RBBM_CMDFIFO_ADDR, i);
value = RREG32(RADEON_RBBM_CMDFIFO_DATA);
seq_printf(m, "[0x%03X] 0x%04X=0x%08X\n", i, reg, value);
}
return 0;
}
static int r100_debugfs_cp_ring_info(struct seq_file *m, void *data)
{
struct drm_info_node *node = (struct drm_info_node *) m->private;
struct drm_device *dev = node->minor->dev;
struct radeon_device *rdev = dev->dev_private;
uint32_t rdp, wdp;
unsigned count, i, j;
radeon_ring_free_size(rdev);
rdp = RREG32(RADEON_CP_RB_RPTR);
wdp = RREG32(RADEON_CP_RB_WPTR);
count = (rdp + rdev->cp.ring_size - wdp) & rdev->cp.ptr_mask;
seq_printf(m, "CP_STAT 0x%08x\n", RREG32(RADEON_CP_STAT));
seq_printf(m, "CP_RB_WPTR 0x%08x\n", wdp);
seq_printf(m, "CP_RB_RPTR 0x%08x\n", rdp);
seq_printf(m, "%u free dwords in ring\n", rdev->cp.ring_free_dw);
seq_printf(m, "%u dwords in ring\n", count);
for (j = 0; j <= count; j++) {
i = (rdp + j) & rdev->cp.ptr_mask;
seq_printf(m, "r[%04d]=0x%08x\n", i, rdev->cp.ring[i]);
}
return 0;
}
static int r100_debugfs_cp_csq_fifo(struct seq_file *m, void *data)
{
struct drm_info_node *node = (struct drm_info_node *) m->private;
struct drm_device *dev = node->minor->dev;
struct radeon_device *rdev = dev->dev_private;
uint32_t csq_stat, csq2_stat, tmp;
unsigned r_rptr, r_wptr, ib1_rptr, ib1_wptr, ib2_rptr, ib2_wptr;
unsigned i;
seq_printf(m, "CP_STAT 0x%08x\n", RREG32(RADEON_CP_STAT));
seq_printf(m, "CP_CSQ_MODE 0x%08x\n", RREG32(RADEON_CP_CSQ_MODE));
csq_stat = RREG32(RADEON_CP_CSQ_STAT);
csq2_stat = RREG32(RADEON_CP_CSQ2_STAT);
r_rptr = (csq_stat >> 0) & 0x3ff;
r_wptr = (csq_stat >> 10) & 0x3ff;
ib1_rptr = (csq_stat >> 20) & 0x3ff;
ib1_wptr = (csq2_stat >> 0) & 0x3ff;
ib2_rptr = (csq2_stat >> 10) & 0x3ff;
ib2_wptr = (csq2_stat >> 20) & 0x3ff;
seq_printf(m, "CP_CSQ_STAT 0x%08x\n", csq_stat);
seq_printf(m, "CP_CSQ2_STAT 0x%08x\n", csq2_stat);
seq_printf(m, "Ring rptr %u\n", r_rptr);
seq_printf(m, "Ring wptr %u\n", r_wptr);
seq_printf(m, "Indirect1 rptr %u\n", ib1_rptr);
seq_printf(m, "Indirect1 wptr %u\n", ib1_wptr);
seq_printf(m, "Indirect2 rptr %u\n", ib2_rptr);
seq_printf(m, "Indirect2 wptr %u\n", ib2_wptr);
/* FIXME: 0, 128, 640 depends on fifo setup see cp_init_kms
* 128 = indirect1_start * 8 & 640 = indirect2_start * 8 */
seq_printf(m, "Ring fifo:\n");
for (i = 0; i < 256; i++) {
WREG32(RADEON_CP_CSQ_ADDR, i << 2);
tmp = RREG32(RADEON_CP_CSQ_DATA);
seq_printf(m, "rfifo[%04d]=0x%08X\n", i, tmp);
}
seq_printf(m, "Indirect1 fifo:\n");
for (i = 256; i <= 512; i++) {
WREG32(RADEON_CP_CSQ_ADDR, i << 2);
tmp = RREG32(RADEON_CP_CSQ_DATA);
seq_printf(m, "ib1fifo[%04d]=0x%08X\n", i, tmp);
}
seq_printf(m, "Indirect2 fifo:\n");
for (i = 640; i < ib1_wptr; i++) {
WREG32(RADEON_CP_CSQ_ADDR, i << 2);
tmp = RREG32(RADEON_CP_CSQ_DATA);
seq_printf(m, "ib2fifo[%04d]=0x%08X\n", i, tmp);
}
return 0;
}
static int r100_debugfs_mc_info(struct seq_file *m, void *data)
{
struct drm_info_node *node = (struct drm_info_node *) m->private;
struct drm_device *dev = node->minor->dev;
struct radeon_device *rdev = dev->dev_private;
uint32_t tmp;
tmp = RREG32(RADEON_CONFIG_MEMSIZE);
seq_printf(m, "CONFIG_MEMSIZE 0x%08x\n", tmp);
tmp = RREG32(RADEON_MC_FB_LOCATION);
seq_printf(m, "MC_FB_LOCATION 0x%08x\n", tmp);
tmp = RREG32(RADEON_BUS_CNTL);
seq_printf(m, "BUS_CNTL 0x%08x\n", tmp);
tmp = RREG32(RADEON_MC_AGP_LOCATION);
seq_printf(m, "MC_AGP_LOCATION 0x%08x\n", tmp);
tmp = RREG32(RADEON_AGP_BASE);
seq_printf(m, "AGP_BASE 0x%08x\n", tmp);
tmp = RREG32(RADEON_HOST_PATH_CNTL);
seq_printf(m, "HOST_PATH_CNTL 0x%08x\n", tmp);
tmp = RREG32(0x01D0);
seq_printf(m, "AIC_CTRL 0x%08x\n", tmp);
tmp = RREG32(RADEON_AIC_LO_ADDR);
seq_printf(m, "AIC_LO_ADDR 0x%08x\n", tmp);
tmp = RREG32(RADEON_AIC_HI_ADDR);
seq_printf(m, "AIC_HI_ADDR 0x%08x\n", tmp);
tmp = RREG32(0x01E4);
seq_printf(m, "AIC_TLB_ADDR 0x%08x\n", tmp);
return 0;
}
static struct drm_info_list r100_debugfs_rbbm_list[] = {
{"r100_rbbm_info", r100_debugfs_rbbm_info, 0, NULL},
};
static struct drm_info_list r100_debugfs_cp_list[] = {
{"r100_cp_ring_info", r100_debugfs_cp_ring_info, 0, NULL},
{"r100_cp_csq_fifo", r100_debugfs_cp_csq_fifo, 0, NULL},
};
static struct drm_info_list r100_debugfs_mc_info_list[] = {
{"r100_mc_info", r100_debugfs_mc_info, 0, NULL},
};
#endif
int r100_debugfs_rbbm_init(struct radeon_device *rdev)
{
#if defined(CONFIG_DEBUG_FS)
return radeon_debugfs_add_files(rdev, r100_debugfs_rbbm_list, 1);
#else
return 0;
#endif
}
int r100_debugfs_cp_init(struct radeon_device *rdev)
{
#if defined(CONFIG_DEBUG_FS)
return radeon_debugfs_add_files(rdev, r100_debugfs_cp_list, 2);
#else
return 0;
#endif
}
int r100_debugfs_mc_info_init(struct radeon_device *rdev)
{
#if defined(CONFIG_DEBUG_FS)
return radeon_debugfs_add_files(rdev, r100_debugfs_mc_info_list, 1);
#else
return 0;
#endif
}
int r100_set_surface_reg(struct radeon_device *rdev, int reg,
uint32_t tiling_flags, uint32_t pitch,
uint32_t offset, uint32_t obj_size)
{
int surf_index = reg * 16;
int flags = 0;
/* r100/r200 divide by 16 */
if (rdev->family < CHIP_R300)
flags = pitch / 16;
else
flags = pitch / 8;
if (rdev->family <= CHIP_RS200) {
if ((tiling_flags & (RADEON_TILING_MACRO|RADEON_TILING_MICRO))
== (RADEON_TILING_MACRO|RADEON_TILING_MICRO))
flags |= RADEON_SURF_TILE_COLOR_BOTH;
if (tiling_flags & RADEON_TILING_MACRO)
flags |= RADEON_SURF_TILE_COLOR_MACRO;
} else if (rdev->family <= CHIP_RV280) {
if (tiling_flags & (RADEON_TILING_MACRO))
flags |= R200_SURF_TILE_COLOR_MACRO;
if (tiling_flags & RADEON_TILING_MICRO)
flags |= R200_SURF_TILE_COLOR_MICRO;
} else {
if (tiling_flags & RADEON_TILING_MACRO)
flags |= R300_SURF_TILE_MACRO;
if (tiling_flags & RADEON_TILING_MICRO)
flags |= R300_SURF_TILE_MICRO;
}
DRM_DEBUG("writing surface %d %d %x %x\n", reg, flags, offset, offset+obj_size-1);
WREG32(RADEON_SURFACE0_INFO + surf_index, flags);
WREG32(RADEON_SURFACE0_LOWER_BOUND + surf_index, offset);
WREG32(RADEON_SURFACE0_UPPER_BOUND + surf_index, offset + obj_size - 1);
return 0;
}
void r100_clear_surface_reg(struct radeon_device *rdev, int reg)
{
int surf_index = reg * 16;
WREG32(RADEON_SURFACE0_INFO + surf_index, 0);
}
void r100_bandwidth_update(struct radeon_device *rdev)
{
fixed20_12 trcd_ff, trp_ff, tras_ff, trbs_ff, tcas_ff;
fixed20_12 sclk_ff, mclk_ff, sclk_eff_ff, sclk_delay_ff;
fixed20_12 peak_disp_bw, mem_bw, pix_clk, pix_clk2, temp_ff, crit_point_ff;
uint32_t temp, data, mem_trcd, mem_trp, mem_tras;
fixed20_12 memtcas_ff[8] = {
fixed_init(1),
fixed_init(2),
fixed_init(3),
fixed_init(0),
fixed_init_half(1),
fixed_init_half(2),
fixed_init(0),
};
fixed20_12 memtcas_rs480_ff[8] = {
fixed_init(0),
fixed_init(1),
fixed_init(2),
fixed_init(3),
fixed_init(0),
fixed_init_half(1),
fixed_init_half(2),
fixed_init_half(3),
};
fixed20_12 memtcas2_ff[8] = {
fixed_init(0),
fixed_init(1),
fixed_init(2),
fixed_init(3),
fixed_init(4),
fixed_init(5),
fixed_init(6),
fixed_init(7),
};
fixed20_12 memtrbs[8] = {
fixed_init(1),
fixed_init_half(1),
fixed_init(2),
fixed_init_half(2),
fixed_init(3),
fixed_init_half(3),
fixed_init(4),
fixed_init_half(4)
};
fixed20_12 memtrbs_r4xx[8] = {
fixed_init(4),
fixed_init(5),
fixed_init(6),
fixed_init(7),
fixed_init(8),
fixed_init(9),
fixed_init(10),
fixed_init(11)
};
fixed20_12 min_mem_eff;
fixed20_12 mc_latency_sclk, mc_latency_mclk, k1;
fixed20_12 cur_latency_mclk, cur_latency_sclk;
fixed20_12 disp_latency, disp_latency_overhead, disp_drain_rate,
disp_drain_rate2, read_return_rate;
fixed20_12 time_disp1_drop_priority;
int c;
int cur_size = 16; /* in octawords */
int critical_point = 0, critical_point2;
/* uint32_t read_return_rate, time_disp1_drop_priority; */
int stop_req, max_stop_req;
struct drm_display_mode *mode1 = NULL;
struct drm_display_mode *mode2 = NULL;
uint32_t pixel_bytes1 = 0;
uint32_t pixel_bytes2 = 0;
if (rdev->mode_info.crtcs[0]->base.enabled) {
mode1 = &rdev->mode_info.crtcs[0]->base.mode;
pixel_bytes1 = rdev->mode_info.crtcs[0]->base.fb->bits_per_pixel / 8;
}
if (rdev->mode_info.crtcs[1]->base.enabled) {
mode2 = &rdev->mode_info.crtcs[1]->base.mode;
pixel_bytes2 = rdev->mode_info.crtcs[1]->base.fb->bits_per_pixel / 8;
}
min_mem_eff.full = rfixed_const_8(0);
/* get modes */
if ((rdev->disp_priority == 2) && ASIC_IS_R300(rdev)) {
uint32_t mc_init_misc_lat_timer = RREG32(R300_MC_INIT_MISC_LAT_TIMER);
mc_init_misc_lat_timer &= ~(R300_MC_DISP1R_INIT_LAT_MASK << R300_MC_DISP1R_INIT_LAT_SHIFT);
mc_init_misc_lat_timer &= ~(R300_MC_DISP0R_INIT_LAT_MASK << R300_MC_DISP0R_INIT_LAT_SHIFT);
/* check crtc enables */
if (mode2)
mc_init_misc_lat_timer |= (1 << R300_MC_DISP1R_INIT_LAT_SHIFT);
if (mode1)
mc_init_misc_lat_timer |= (1 << R300_MC_DISP0R_INIT_LAT_SHIFT);
WREG32(R300_MC_INIT_MISC_LAT_TIMER, mc_init_misc_lat_timer);
}
/*
* determine is there is enough bw for current mode
*/
mclk_ff.full = rfixed_const(rdev->clock.default_mclk);
temp_ff.full = rfixed_const(100);
mclk_ff.full = rfixed_div(mclk_ff, temp_ff);
sclk_ff.full = rfixed_const(rdev->clock.default_sclk);
sclk_ff.full = rfixed_div(sclk_ff, temp_ff);
temp = (rdev->mc.vram_width / 8) * (rdev->mc.vram_is_ddr ? 2 : 1);
temp_ff.full = rfixed_const(temp);
mem_bw.full = rfixed_mul(mclk_ff, temp_ff);
pix_clk.full = 0;
pix_clk2.full = 0;
peak_disp_bw.full = 0;
if (mode1) {
temp_ff.full = rfixed_const(1000);
pix_clk.full = rfixed_const(mode1->clock); /* convert to fixed point */
pix_clk.full = rfixed_div(pix_clk, temp_ff);
temp_ff.full = rfixed_const(pixel_bytes1);
peak_disp_bw.full += rfixed_mul(pix_clk, temp_ff);
}
if (mode2) {
temp_ff.full = rfixed_const(1000);
pix_clk2.full = rfixed_const(mode2->clock); /* convert to fixed point */
pix_clk2.full = rfixed_div(pix_clk2, temp_ff);
temp_ff.full = rfixed_const(pixel_bytes2);
peak_disp_bw.full += rfixed_mul(pix_clk2, temp_ff);
}
mem_bw.full = rfixed_mul(mem_bw, min_mem_eff);
if (peak_disp_bw.full >= mem_bw.full) {
DRM_ERROR("You may not have enough display bandwidth for current mode\n"
"If you have flickering problem, try to lower resolution, refresh rate, or color depth\n");
}
/* Get values from the EXT_MEM_CNTL register...converting its contents. */
temp = RREG32(RADEON_MEM_TIMING_CNTL);
if ((rdev->family == CHIP_RV100) || (rdev->flags & RADEON_IS_IGP)) { /* RV100, M6, IGPs */
mem_trcd = ((temp >> 2) & 0x3) + 1;
mem_trp = ((temp & 0x3)) + 1;
mem_tras = ((temp & 0x70) >> 4) + 1;
} else if (rdev->family == CHIP_R300 ||
rdev->family == CHIP_R350) { /* r300, r350 */
mem_trcd = (temp & 0x7) + 1;
mem_trp = ((temp >> 8) & 0x7) + 1;
mem_tras = ((temp >> 11) & 0xf) + 4;
} else if (rdev->family == CHIP_RV350 ||
rdev->family <= CHIP_RV380) {
/* rv3x0 */
mem_trcd = (temp & 0x7) + 3;
mem_trp = ((temp >> 8) & 0x7) + 3;
mem_tras = ((temp >> 11) & 0xf) + 6;
} else if (rdev->family == CHIP_R420 ||
rdev->family == CHIP_R423 ||
rdev->family == CHIP_RV410) {
/* r4xx */
mem_trcd = (temp & 0xf) + 3;
if (mem_trcd > 15)
mem_trcd = 15;
mem_trp = ((temp >> 8) & 0xf) + 3;
if (mem_trp > 15)
mem_trp = 15;
mem_tras = ((temp >> 12) & 0x1f) + 6;
if (mem_tras > 31)
mem_tras = 31;
} else { /* RV200, R200 */
mem_trcd = (temp & 0x7) + 1;
mem_trp = ((temp >> 8) & 0x7) + 1;
mem_tras = ((temp >> 12) & 0xf) + 4;
}
/* convert to FF */
trcd_ff.full = rfixed_const(mem_trcd);
trp_ff.full = rfixed_const(mem_trp);
tras_ff.full = rfixed_const(mem_tras);
/* Get values from the MEM_SDRAM_MODE_REG register...converting its */
temp = RREG32(RADEON_MEM_SDRAM_MODE_REG);
data = (temp & (7 << 20)) >> 20;
if ((rdev->family == CHIP_RV100) || rdev->flags & RADEON_IS_IGP) {
if (rdev->family == CHIP_RS480) /* don't think rs400 */
tcas_ff = memtcas_rs480_ff[data];
else
tcas_ff = memtcas_ff[data];
} else
tcas_ff = memtcas2_ff[data];
if (rdev->family == CHIP_RS400 ||
rdev->family == CHIP_RS480) {
/* extra cas latency stored in bits 23-25 0-4 clocks */
data = (temp >> 23) & 0x7;
if (data < 5)
tcas_ff.full += rfixed_const(data);
}
if (ASIC_IS_R300(rdev) && !(rdev->flags & RADEON_IS_IGP)) {
/* on the R300, Tcas is included in Trbs.
*/
temp = RREG32(RADEON_MEM_CNTL);
data = (R300_MEM_NUM_CHANNELS_MASK & temp);
if (data == 1) {
if (R300_MEM_USE_CD_CH_ONLY & temp) {
temp = RREG32(R300_MC_IND_INDEX);
temp &= ~R300_MC_IND_ADDR_MASK;
temp |= R300_MC_READ_CNTL_CD_mcind;
WREG32(R300_MC_IND_INDEX, temp);
temp = RREG32(R300_MC_IND_DATA);
data = (R300_MEM_RBS_POSITION_C_MASK & temp);
} else {
temp = RREG32(R300_MC_READ_CNTL_AB);
data = (R300_MEM_RBS_POSITION_A_MASK & temp);
}
} else {
temp = RREG32(R300_MC_READ_CNTL_AB);
data = (R300_MEM_RBS_POSITION_A_MASK & temp);
}
if (rdev->family == CHIP_RV410 ||
rdev->family == CHIP_R420 ||
rdev->family == CHIP_R423)
trbs_ff = memtrbs_r4xx[data];
else
trbs_ff = memtrbs[data];
tcas_ff.full += trbs_ff.full;
}
sclk_eff_ff.full = sclk_ff.full;
if (rdev->flags & RADEON_IS_AGP) {
fixed20_12 agpmode_ff;
agpmode_ff.full = rfixed_const(radeon_agpmode);
temp_ff.full = rfixed_const_666(16);
sclk_eff_ff.full -= rfixed_mul(agpmode_ff, temp_ff);
}
/* TODO PCIE lanes may affect this - agpmode == 16?? */
if (ASIC_IS_R300(rdev)) {
sclk_delay_ff.full = rfixed_const(250);
} else {
if ((rdev->family == CHIP_RV100) ||
rdev->flags & RADEON_IS_IGP) {
if (rdev->mc.vram_is_ddr)
sclk_delay_ff.full = rfixed_const(41);
else
sclk_delay_ff.full = rfixed_const(33);
} else {
if (rdev->mc.vram_width == 128)
sclk_delay_ff.full = rfixed_const(57);
else
sclk_delay_ff.full = rfixed_const(41);
}
}
mc_latency_sclk.full = rfixed_div(sclk_delay_ff, sclk_eff_ff);
if (rdev->mc.vram_is_ddr) {
if (rdev->mc.vram_width == 32) {
k1.full = rfixed_const(40);
c = 3;
} else {
k1.full = rfixed_const(20);
c = 1;
}
} else {
k1.full = rfixed_const(40);
c = 3;
}
temp_ff.full = rfixed_const(2);
mc_latency_mclk.full = rfixed_mul(trcd_ff, temp_ff);
temp_ff.full = rfixed_const(c);
mc_latency_mclk.full += rfixed_mul(tcas_ff, temp_ff);
temp_ff.full = rfixed_const(4);
mc_latency_mclk.full += rfixed_mul(tras_ff, temp_ff);
mc_latency_mclk.full += rfixed_mul(trp_ff, temp_ff);
mc_latency_mclk.full += k1.full;
mc_latency_mclk.full = rfixed_div(mc_latency_mclk, mclk_ff);
mc_latency_mclk.full += rfixed_div(temp_ff, sclk_eff_ff);
/*
HW cursor time assuming worst case of full size colour cursor.
*/
temp_ff.full = rfixed_const((2 * (cur_size - (rdev->mc.vram_is_ddr + 1))));
temp_ff.full += trcd_ff.full;
if (temp_ff.full < tras_ff.full)
temp_ff.full = tras_ff.full;
cur_latency_mclk.full = rfixed_div(temp_ff, mclk_ff);
temp_ff.full = rfixed_const(cur_size);
cur_latency_sclk.full = rfixed_div(temp_ff, sclk_eff_ff);
/*
Find the total latency for the display data.
*/
disp_latency_overhead.full = rfixed_const(80);
disp_latency_overhead.full = rfixed_div(disp_latency_overhead, sclk_ff);
mc_latency_mclk.full += disp_latency_overhead.full + cur_latency_mclk.full;
mc_latency_sclk.full += disp_latency_overhead.full + cur_latency_sclk.full;
if (mc_latency_mclk.full > mc_latency_sclk.full)
disp_latency.full = mc_latency_mclk.full;
else
disp_latency.full = mc_latency_sclk.full;
/* setup Max GRPH_STOP_REQ default value */
if (ASIC_IS_RV100(rdev))
max_stop_req = 0x5c;
else
max_stop_req = 0x7c;
if (mode1) {
/* CRTC1
Set GRPH_BUFFER_CNTL register using h/w defined optimal values.
GRPH_STOP_REQ <= MIN[ 0x7C, (CRTC_H_DISP + 1) * (bit depth) / 0x10 ]
*/
stop_req = mode1->hdisplay * pixel_bytes1 / 16;
if (stop_req > max_stop_req)
stop_req = max_stop_req;
/*
Find the drain rate of the display buffer.
*/
temp_ff.full = rfixed_const((16/pixel_bytes1));
disp_drain_rate.full = rfixed_div(pix_clk, temp_ff);
/*
Find the critical point of the display buffer.
*/
crit_point_ff.full = rfixed_mul(disp_drain_rate, disp_latency);
crit_point_ff.full += rfixed_const_half(0);
critical_point = rfixed_trunc(crit_point_ff);
if (rdev->disp_priority == 2) {
critical_point = 0;
}
/*
The critical point should never be above max_stop_req-4. Setting
GRPH_CRITICAL_CNTL = 0 will thus force high priority all the time.
*/
if (max_stop_req - critical_point < 4)
critical_point = 0;
if (critical_point == 0 && mode2 && rdev->family == CHIP_R300) {
/* some R300 cards have problem with this set to 0, when CRTC2 is enabled.*/
critical_point = 0x10;
}
temp = RREG32(RADEON_GRPH_BUFFER_CNTL);
temp &= ~(RADEON_GRPH_STOP_REQ_MASK);
temp |= (stop_req << RADEON_GRPH_STOP_REQ_SHIFT);
temp &= ~(RADEON_GRPH_START_REQ_MASK);
if ((rdev->family == CHIP_R350) &&
(stop_req > 0x15)) {
stop_req -= 0x10;
}
temp |= (stop_req << RADEON_GRPH_START_REQ_SHIFT);
temp |= RADEON_GRPH_BUFFER_SIZE;
temp &= ~(RADEON_GRPH_CRITICAL_CNTL |
RADEON_GRPH_CRITICAL_AT_SOF |
RADEON_GRPH_STOP_CNTL);
/*
Write the result into the register.
*/
WREG32(RADEON_GRPH_BUFFER_CNTL, ((temp & ~RADEON_GRPH_CRITICAL_POINT_MASK) |
(critical_point << RADEON_GRPH_CRITICAL_POINT_SHIFT)));
#if 0
if ((rdev->family == CHIP_RS400) ||
(rdev->family == CHIP_RS480)) {
/* attempt to program RS400 disp regs correctly ??? */
temp = RREG32(RS400_DISP1_REG_CNTL);
temp &= ~(RS400_DISP1_START_REQ_LEVEL_MASK |
RS400_DISP1_STOP_REQ_LEVEL_MASK);
WREG32(RS400_DISP1_REQ_CNTL1, (temp |
(critical_point << RS400_DISP1_START_REQ_LEVEL_SHIFT) |
(critical_point << RS400_DISP1_STOP_REQ_LEVEL_SHIFT)));
temp = RREG32(RS400_DMIF_MEM_CNTL1);
temp &= ~(RS400_DISP1_CRITICAL_POINT_START_MASK |
RS400_DISP1_CRITICAL_POINT_STOP_MASK);
WREG32(RS400_DMIF_MEM_CNTL1, (temp |
(critical_point << RS400_DISP1_CRITICAL_POINT_START_SHIFT) |
(critical_point << RS400_DISP1_CRITICAL_POINT_STOP_SHIFT)));
}
#endif
DRM_DEBUG("GRPH_BUFFER_CNTL from to %x\n",
/* (unsigned int)info->SavedReg->grph_buffer_cntl, */
(unsigned int)RREG32(RADEON_GRPH_BUFFER_CNTL));
}
if (mode2) {
u32 grph2_cntl;
stop_req = mode2->hdisplay * pixel_bytes2 / 16;
if (stop_req > max_stop_req)
stop_req = max_stop_req;
/*
Find the drain rate of the display buffer.
*/
temp_ff.full = rfixed_const((16/pixel_bytes2));
disp_drain_rate2.full = rfixed_div(pix_clk2, temp_ff);
grph2_cntl = RREG32(RADEON_GRPH2_BUFFER_CNTL);
grph2_cntl &= ~(RADEON_GRPH_STOP_REQ_MASK);
grph2_cntl |= (stop_req << RADEON_GRPH_STOP_REQ_SHIFT);
grph2_cntl &= ~(RADEON_GRPH_START_REQ_MASK);
if ((rdev->family == CHIP_R350) &&
(stop_req > 0x15)) {
stop_req -= 0x10;
}
grph2_cntl |= (stop_req << RADEON_GRPH_START_REQ_SHIFT);
grph2_cntl |= RADEON_GRPH_BUFFER_SIZE;
grph2_cntl &= ~(RADEON_GRPH_CRITICAL_CNTL |
RADEON_GRPH_CRITICAL_AT_SOF |
RADEON_GRPH_STOP_CNTL);
if ((rdev->family == CHIP_RS100) ||
(rdev->family == CHIP_RS200))
critical_point2 = 0;
else {
temp = (rdev->mc.vram_width * rdev->mc.vram_is_ddr + 1)/128;
temp_ff.full = rfixed_const(temp);
temp_ff.full = rfixed_mul(mclk_ff, temp_ff);
if (sclk_ff.full < temp_ff.full)
temp_ff.full = sclk_ff.full;
read_return_rate.full = temp_ff.full;
if (mode1) {
temp_ff.full = read_return_rate.full - disp_drain_rate.full;
time_disp1_drop_priority.full = rfixed_div(crit_point_ff, temp_ff);
} else {
time_disp1_drop_priority.full = 0;
}
crit_point_ff.full = disp_latency.full + time_disp1_drop_priority.full + disp_latency.full;
crit_point_ff.full = rfixed_mul(crit_point_ff, disp_drain_rate2);
crit_point_ff.full += rfixed_const_half(0);
critical_point2 = rfixed_trunc(crit_point_ff);
if (rdev->disp_priority == 2) {
critical_point2 = 0;
}
if (max_stop_req - critical_point2 < 4)
critical_point2 = 0;
}
if (critical_point2 == 0 && rdev->family == CHIP_R300) {
/* some R300 cards have problem with this set to 0 */
critical_point2 = 0x10;
}
WREG32(RADEON_GRPH2_BUFFER_CNTL, ((grph2_cntl & ~RADEON_GRPH_CRITICAL_POINT_MASK) |
(critical_point2 << RADEON_GRPH_CRITICAL_POINT_SHIFT)));
if ((rdev->family == CHIP_RS400) ||
(rdev->family == CHIP_RS480)) {
#if 0
/* attempt to program RS400 disp2 regs correctly ??? */
temp = RREG32(RS400_DISP2_REQ_CNTL1);
temp &= ~(RS400_DISP2_START_REQ_LEVEL_MASK |
RS400_DISP2_STOP_REQ_LEVEL_MASK);
WREG32(RS400_DISP2_REQ_CNTL1, (temp |
(critical_point2 << RS400_DISP1_START_REQ_LEVEL_SHIFT) |
(critical_point2 << RS400_DISP1_STOP_REQ_LEVEL_SHIFT)));
temp = RREG32(RS400_DISP2_REQ_CNTL2);
temp &= ~(RS400_DISP2_CRITICAL_POINT_START_MASK |
RS400_DISP2_CRITICAL_POINT_STOP_MASK);
WREG32(RS400_DISP2_REQ_CNTL2, (temp |
(critical_point2 << RS400_DISP2_CRITICAL_POINT_START_SHIFT) |
(critical_point2 << RS400_DISP2_CRITICAL_POINT_STOP_SHIFT)));
#endif
WREG32(RS400_DISP2_REQ_CNTL1, 0x105DC1CC);
WREG32(RS400_DISP2_REQ_CNTL2, 0x2749D000);
WREG32(RS400_DMIF_MEM_CNTL1, 0x29CA71DC);
WREG32(RS400_DISP1_REQ_CNTL1, 0x28FBC3AC);
}
DRM_DEBUG("GRPH2_BUFFER_CNTL from to %x\n",
(unsigned int)RREG32(RADEON_GRPH2_BUFFER_CNTL));
}
}