wlroots/backend/drm/util.c

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#include <assert.h>
#include <drm_fourcc.h>
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#include <drm_mode.h>
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#include <drm.h>
#include <libdisplay-info/cvt.h>
#include <libdisplay-info/edid.h>
#include <libdisplay-info/info.h>
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#include <stdio.h>
#include <stdlib.h>
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#include <string.h>
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#include <wlr/util/log.h>
#include "backend/drm/drm.h"
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#include "backend/drm/util.h"
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int32_t calculate_refresh_rate(const drmModeModeInfo *mode) {
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int32_t refresh = (mode->clock * 1000000LL / mode->htotal +
mode->vtotal / 2) / mode->vtotal;
if (mode->flags & DRM_MODE_FLAG_INTERLACE) {
refresh *= 2;
}
if (mode->flags & DRM_MODE_FLAG_DBLSCAN) {
refresh /= 2;
}
if (mode->vscan > 1) {
refresh /= mode->vscan;
}
return refresh;
}
enum wlr_output_mode_aspect_ratio get_picture_aspect_ratio(const drmModeModeInfo *mode) {
switch (mode->flags & DRM_MODE_FLAG_PIC_AR_MASK) {
case DRM_MODE_FLAG_PIC_AR_NONE:
return WLR_OUTPUT_MODE_ASPECT_RATIO_NONE;
case DRM_MODE_FLAG_PIC_AR_4_3:
return WLR_OUTPUT_MODE_ASPECT_RATIO_4_3;
case DRM_MODE_FLAG_PIC_AR_16_9:
return WLR_OUTPUT_MODE_ASPECT_RATIO_16_9;
case DRM_MODE_FLAG_PIC_AR_64_27:
return WLR_OUTPUT_MODE_ASPECT_RATIO_64_27;
case DRM_MODE_FLAG_PIC_AR_256_135:
return WLR_OUTPUT_MODE_ASPECT_RATIO_256_135;
default:
wlr_log(WLR_ERROR, "Unknown mode picture aspect ratio: %u",
mode->flags & DRM_MODE_FLAG_PIC_AR_MASK);
return WLR_OUTPUT_MODE_ASPECT_RATIO_NONE;
}
}
void parse_edid(struct wlr_drm_connector *conn, size_t len, const uint8_t *data) {
struct wlr_output *output = &conn->output;
free(output->make);
free(output->model);
free(output->serial);
output->make = NULL;
output->model = NULL;
output->serial = NULL;
struct di_info *info = di_info_parse_edid(data, len);
if (info == NULL) {
wlr_log(WLR_ERROR, "Failed to parse EDID");
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return;
}
const struct di_edid *edid = di_info_get_edid(info);
const struct di_edid_vendor_product *vendor_product = di_edid_get_vendor_product(edid);
char pnp_id[] = {
vendor_product->manufacturer[0],
vendor_product->manufacturer[1],
vendor_product->manufacturer[2],
'\0',
};
const char *manu = get_pnp_manufacturer(vendor_product->manufacturer);
if (!manu) {
manu = pnp_id;
}
output->make = strdup(manu);
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output->model = di_info_get_model(info);
output->serial = di_info_get_serial(info);
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di_info_destroy(info);
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}
const char *drm_connector_status_str(drmModeConnection status) {
switch (status) {
case DRM_MODE_CONNECTED:
return "connected";
case DRM_MODE_DISCONNECTED:
return "disconnected";
case DRM_MODE_UNKNOWNCONNECTION:
return "unknown";
}
return "<unsupported>";
}
static bool is_taken(size_t n, const uint32_t arr[static n], uint32_t key) {
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for (size_t i = 0; i < n; ++i) {
if (arr[i] == key) {
return true;
}
}
return false;
}
/*
* Store all of the non-recursive state in a struct, so we aren't literally
* passing 12 arguments to a function.
*/
struct match_state {
const size_t num_conns;
const uint32_t *restrict conns;
const size_t num_crtcs;
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size_t score;
size_t replaced;
uint32_t *restrict res;
uint32_t *restrict best;
const uint32_t *restrict orig;
bool exit_early;
};
/**
* Step to process a CRTC.
*
* This is a naive implementation of maximum bipartite matching.
*
* score: The number of connectors we've matched so far.
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* replaced: The number of changes from the original solution.
* crtc_index: The index of the current CRTC.
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*
* This tries to match a solution as close to st->orig as it can.
*
* Returns whether we've set a new best element with this solution.
*/
static bool match_connectors_with_crtcs_(struct match_state *st,
size_t score, size_t replaced, size_t crtc_index) {
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// Finished
if (crtc_index >= st->num_crtcs) {
backend/drm: steal CRTCs from disabled outputs This commit allows outputs that need a CRTC to steal it from user-disabled outputs. Note that in the case there are enough CRTCs, disabled outputs don't loose it (so there's no modeset and plane initialization needed after DPMS). CRTC allocation still prefers to keep the old configuration, even if that means allocating an extra CRTC to a disabled output. CRTC reallocation now happen when enabling/disabling an output as well as when trying to modeset. When enabling an output without a CRTC, we realloc to try to steal a CRTC from a disabled output (that doesn't really need the CRTC). When disabling an output, we try to give our CRTC to an output that needs one. Modesetting is similar to enabling. A new DRM connector field has been added: `desired_enabled`. Outputs without CRTCs get automatically disabled. This field keeps track of the state desired by the user, allowing to automatically re-enable outputs when a CRTC becomes free. This required some changes to the allocation algorithm. Previously, the algorithm tried to keep the previous configuration even if a new configuration with a better score was possible (it only changed configuration when the old one didn't work anymore). This is now changed and the old configuration (still preferred) is only retained without considering new possibilities when it's perfect (all outputs have CRTCs). User-disabled outputs now have `possible_crtcs` set to 0, meaning they can only retain a previous CRTC (not acquire a new one). The allocation algorithm has been updated to do not bump the score when assigning a CRTC to a disabled output.
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if (score > st->score ||
(score == st->score && replaced < st->replaced)) {
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st->score = score;
st->replaced = replaced;
memcpy(st->best, st->res, sizeof(st->best[0]) * st->num_crtcs);
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st->exit_early = (st->score == st->num_crtcs
|| st->score == st->num_conns)
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&& st->replaced == 0;
return true;
} else {
return false;
}
}
backend/drm: steal CRTCs from disabled outputs This commit allows outputs that need a CRTC to steal it from user-disabled outputs. Note that in the case there are enough CRTCs, disabled outputs don't loose it (so there's no modeset and plane initialization needed after DPMS). CRTC allocation still prefers to keep the old configuration, even if that means allocating an extra CRTC to a disabled output. CRTC reallocation now happen when enabling/disabling an output as well as when trying to modeset. When enabling an output without a CRTC, we realloc to try to steal a CRTC from a disabled output (that doesn't really need the CRTC). When disabling an output, we try to give our CRTC to an output that needs one. Modesetting is similar to enabling. A new DRM connector field has been added: `desired_enabled`. Outputs without CRTCs get automatically disabled. This field keeps track of the state desired by the user, allowing to automatically re-enable outputs when a CRTC becomes free. This required some changes to the allocation algorithm. Previously, the algorithm tried to keep the previous configuration even if a new configuration with a better score was possible (it only changed configuration when the old one didn't work anymore). This is now changed and the old configuration (still preferred) is only retained without considering new possibilities when it's perfect (all outputs have CRTCs). User-disabled outputs now have `possible_crtcs` set to 0, meaning they can only retain a previous CRTC (not acquire a new one). The allocation algorithm has been updated to do not bump the score when assigning a CRTC to a disabled output.
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bool has_best = false;
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/*
* Attempt to use the current solution first, to try and avoid
* recalculating everything
*/
if (st->orig[crtc_index] != UNMATCHED && !is_taken(crtc_index, st->res, st->orig[crtc_index])) {
st->res[crtc_index] = st->orig[crtc_index];
size_t crtc_score = st->conns[st->res[crtc_index]] != 0 ? 1 : 0;
if (match_connectors_with_crtcs_(st, score + crtc_score, replaced, crtc_index + 1)) {
backend/drm: steal CRTCs from disabled outputs This commit allows outputs that need a CRTC to steal it from user-disabled outputs. Note that in the case there are enough CRTCs, disabled outputs don't loose it (so there's no modeset and plane initialization needed after DPMS). CRTC allocation still prefers to keep the old configuration, even if that means allocating an extra CRTC to a disabled output. CRTC reallocation now happen when enabling/disabling an output as well as when trying to modeset. When enabling an output without a CRTC, we realloc to try to steal a CRTC from a disabled output (that doesn't really need the CRTC). When disabling an output, we try to give our CRTC to an output that needs one. Modesetting is similar to enabling. A new DRM connector field has been added: `desired_enabled`. Outputs without CRTCs get automatically disabled. This field keeps track of the state desired by the user, allowing to automatically re-enable outputs when a CRTC becomes free. This required some changes to the allocation algorithm. Previously, the algorithm tried to keep the previous configuration even if a new configuration with a better score was possible (it only changed configuration when the old one didn't work anymore). This is now changed and the old configuration (still preferred) is only retained without considering new possibilities when it's perfect (all outputs have CRTCs). User-disabled outputs now have `possible_crtcs` set to 0, meaning they can only retain a previous CRTC (not acquire a new one). The allocation algorithm has been updated to do not bump the score when assigning a CRTC to a disabled output.
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has_best = true;
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}
}
backend/drm: steal CRTCs from disabled outputs This commit allows outputs that need a CRTC to steal it from user-disabled outputs. Note that in the case there are enough CRTCs, disabled outputs don't loose it (so there's no modeset and plane initialization needed after DPMS). CRTC allocation still prefers to keep the old configuration, even if that means allocating an extra CRTC to a disabled output. CRTC reallocation now happen when enabling/disabling an output as well as when trying to modeset. When enabling an output without a CRTC, we realloc to try to steal a CRTC from a disabled output (that doesn't really need the CRTC). When disabling an output, we try to give our CRTC to an output that needs one. Modesetting is similar to enabling. A new DRM connector field has been added: `desired_enabled`. Outputs without CRTCs get automatically disabled. This field keeps track of the state desired by the user, allowing to automatically re-enable outputs when a CRTC becomes free. This required some changes to the allocation algorithm. Previously, the algorithm tried to keep the previous configuration even if a new configuration with a better score was possible (it only changed configuration when the old one didn't work anymore). This is now changed and the old configuration (still preferred) is only retained without considering new possibilities when it's perfect (all outputs have CRTCs). User-disabled outputs now have `possible_crtcs` set to 0, meaning they can only retain a previous CRTC (not acquire a new one). The allocation algorithm has been updated to do not bump the score when assigning a CRTC to a disabled output.
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if (st->exit_early) {
return true;
}
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if (st->orig[crtc_index] != UNMATCHED) {
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++replaced;
}
for (size_t candidate = 0; candidate < st->num_conns; ++candidate) {
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// We tried this earlier
if (candidate == st->orig[crtc_index]) {
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continue;
}
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// Not compatible
if (!(st->conns[candidate] & (1 << crtc_index))) {
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continue;
}
// Already taken
if (is_taken(crtc_index, st->res, candidate)) {
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continue;
}
st->res[crtc_index] = candidate;
size_t crtc_score = st->conns[candidate] != 0 ? 1 : 0;
if (match_connectors_with_crtcs_(st, score + crtc_score, replaced, crtc_index + 1)) {
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has_best = true;
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}
if (st->exit_early) {
return true;
}
}
// Maybe this CRTC can't be matched
st->res[crtc_index] = UNMATCHED;
if (match_connectors_with_crtcs_(st, score, replaced, crtc_index + 1)) {
has_best = true;
}
return has_best;
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}
void match_connectors_with_crtcs(size_t num_conns,
const uint32_t conns[static restrict num_conns],
size_t num_crtcs, const uint32_t prev_crtcs[static restrict num_crtcs],
uint32_t new_crtcs[static restrict num_crtcs]) {
uint32_t solution[num_crtcs];
for (size_t i = 0; i < num_crtcs; ++i) {
solution[i] = UNMATCHED;
}
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struct match_state st = {
.num_conns = num_conns,
.num_crtcs = num_crtcs,
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.score = 0,
.replaced = SIZE_MAX,
.conns = conns,
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.res = solution,
.best = new_crtcs,
.orig = prev_crtcs,
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.exit_early = false,
};
match_connectors_with_crtcs_(&st, 0, 0, 0);
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}
void generate_cvt_mode(drmModeModeInfo *mode, int hdisplay, int vdisplay,
float vrefresh) {
// TODO: depending on capabilities advertised in the EDID, use reduced
// blanking if possible (and update sync polarity)
struct di_cvt_options options = {
.red_blank_ver = DI_CVT_REDUCED_BLANKING_NONE,
.h_pixels = hdisplay,
.v_lines = vdisplay,
.ip_freq_rqd = vrefresh ? vrefresh : 60,
};
struct di_cvt_timing timing;
di_cvt_compute(&timing, &options);
uint16_t hsync_start = hdisplay + timing.h_front_porch;
uint16_t vsync_start = timing.v_lines_rnd + timing.v_front_porch;
uint16_t hsync_end = hsync_start + timing.h_sync;
uint16_t vsync_end = vsync_start + timing.v_sync;
*mode = (drmModeModeInfo){
.clock = roundf(timing.act_pixel_freq * 1000),
.hdisplay = hdisplay,
.vdisplay = timing.v_lines_rnd,
.hsync_start = hsync_start,
.vsync_start = vsync_start,
.hsync_end = hsync_end,
.vsync_end = vsync_end,
.htotal = hsync_end + timing.h_back_porch,
.vtotal = vsync_end + timing.v_back_porch,
.vrefresh = roundf(timing.act_frame_rate),
.flags = DRM_MODE_FLAG_NHSYNC | DRM_MODE_FLAG_PVSYNC,
};
snprintf(mode->name, sizeof(mode->name), "%dx%d", hdisplay, vdisplay);
}